|
HS Code |
604556 |
| Cas Number | 22230-98-4 |
| Molecular Formula | C6H5F3N2 |
| Molecular Weight | 162.11 |
| Iupac Name | 2-amino-5-(trifluoromethyl)pyridine |
| Appearance | Light yellow to beige solid |
| Boiling Point | 188-190 °C |
| Melting Point | 41-44 °C |
| Purity | Typically ≥98% |
| Density | 1.34 g/cm³ (approximate) |
| Solubility | Soluble in organic solvents like ethanol, DMSO, and methanol |
As an accredited 2-Amino-5-trifuoromethylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Amino-5-trifluoromethylpyridine, 25g, supplied in a tightly sealed amber glass bottle with a tamper-evident screw cap and hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Amino-5-trifluoromethylpyridine: Packed in drums or bags, tightly sealed, safely secured, maximizing container capacity. |
| Shipping | 2-Amino-5-trifluoromethylpyridine is shipped in tightly sealed containers under ambient conditions. It should be protected from moisture and incompatible substances. Packaging complies with regulatory guidelines for chemical transport, labeled for proper identification and hazard information. Handle with care to prevent leakage or breakage during transit. Store in a cool, dry place upon arrival. |
| Storage | 2-Amino-5-trifluoromethylpyridine should be stored in a tightly sealed container, placed in a cool, dry, and well-ventilated area, away from direct sunlight, heat sources, and incompatible substances such as strong oxidizers. Ensure the storage area is equipped with appropriate spill containment measures, and label the container clearly. Store at room temperature and limit exposure to moisture and air. |
| Shelf Life | 2-Amino-5-trifluoromethylpyridine typically has a shelf life of 2-3 years if stored tightly sealed, protected from moisture. |
|
Purity 98%: 2-Amino-5-trifuoromethylpyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and minimal byproduct formation. Melting Point 44-47°C: 2-Amino-5-trifuoromethylpyridine with a melting point of 44-47°C is used in active pharmaceutical ingredient (API) manufacturing, where consistent phase transition supports stable formulation processes. Molecular Weight 164.13 g/mol: 2-Amino-5-trifuoromethylpyridine of molecular weight 164.13 g/mol is used in agrochemical R&D, where precise mass facilitates accurate stoichiometric calculations in compound development. Stability Temperature up to 120°C: 2-Amino-5-trifuoromethylpyridine with stability up to 120°C is used in high-temperature reaction conditions, where its integrity enhances process reliability and safety. Particle Size <50 μm: 2-Amino-5-trifuoromethylpyridine with particle size below 50 μm is used in fine chemical formulations, where superior dispersibility improves homogeneity in final products. Water Content ≤0.2%: 2-Amino-5-trifuoromethylpyridine with water content of no more than 0.2% is used in moisture-sensitive chemical syntheses, where low moisture content prevents unwanted hydrolysis. |
Competitive 2-Amino-5-trifuoromethylpyridine prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@bouling-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@bouling-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Some chemicals get a lot of press; others quietly do their work on the benches of research labs and production facilities. 2-Amino-5-trifluoromethylpyridine, model ATP-2A5TFMP, stands out as one of those compounds that tends to make a real impression on synthetic chemists and process designers alike. This isn’t just another pyridine derivative—though on paper, it might seem that way. The combination of a trifluoromethyl group at the 5-position and an amino group at the 2-position gives this compound unique physical and chemical characteristics that set it apart from many close relatives.
Looking at its structure, the trifluoromethyl group brings the kind of electron-withdrawing power that chemists look for in pharmaceutical design and advanced materials. In my own experience, introducing fluorine atoms or groups into a molecule doesn’t just alter its reactivity. It impacts lipophilicity and bioavailability too. The amino group at position 2 provides a handy anchor point for further reactions—substitution, coupling, you name it.
It can feel like every new building block vies for a place in the market, but 2-Amino-5-trifluoromethylpyridine keeps coming up in both medicinal chemistry and agrochemical research. The fluorinated pyridine core handles a wide array of synthetic challenges. Not every substituted pyridine offers this mix of electron-rich and electron-poor sites, so it’s a favorite when selectivity and reactivity matter.
On the bench, people want reproducibility and solid performance. ATP-2A5TFMP typically comes as an off-white to pale yellow crystalline powder with reliable purity, often above 98%. Melting point sits in a comfortable range for most standard lab handling, which means it doesn’t require outlandish precautions. For researchers tired of struggling with smelly or unstable pyridines, working with this compound is a relief. It also dissolves well in polar organic solvents, making it a flexible partner in reaction setups.
There’s something to be said for a compound that ships as a solid you do not have to baby. Storage in a cool, dry spot keeps it viable, and standard PPE (gloves, glasses, lab coat) more than covers typical handling needs. Comparing this to some of the more notorious pyridine derivatives, where every drip and whiff means a new headache for researchers, 2-Amino-5-trifluoromethylpyridine stands out in its straightforwardness.
Of course, ease of use doesn’t stop at the lab door. Scale-up teams in pharma and agrochemical facilities want predictable behavior and robust shelf life. ATP-2A5TFMP delivers just that, which is why you keep seeing it pop up on product lists from the big and small players alike.
Most buyers seek out 2-Amino-5-trifluoromethylpyridine for its value as an intermediate, and this is where its story gets interesting. In pharma, fluorinated pyridine derivatives often show up in the search for new antiviral drugs, anti-inflammatory agents, and even in cancer research. In my years following drug development trends, I’ve spotted how substituents like trifluoromethyl can push a candidate to stand out in early-stage screening. Adding this group creates molecules that resist metabolic breakdown in the body, which translates into improved drug stability and potentially longer half-life.
The amino group at position 2 isn’t just there for show. It provides a convenient point for coupling to other aromatic or heteroaromatic rings, and for building larger, more complex molecules. Researchers investigating new kinase inhibitors or CNS-active agents often lean on this versatile intermediate because the synthesis steps flow more smoothly, and purification rarely turns into a war.
Crop science teams have come to appreciate the flexibility ATP-2A5TFMP provides in fine-tuning bioactivity for agrochemicals. Pyridine scaffolds already form the backbone of many effective fungicides and herbicides, but fluorinated derivatives often deliver better performance in the field. Resistance is less likely to develop when you fine-tune the molecule’s reactivity or metabolic profile. Here, this compound helps researchers achieve very specific goals—whether that’s persistence in soil, optimal uptake in plants, or safety margins for non-target organisms.
Beyond these mainstays, advanced materials teams play with fluorinated heterocycles to design specialty chemicals, dyes, and polymer additives. The demands might shift—from stability under harsh manufacturing conditions to thermal resistance or modified electrical properties—but the starting point often looks a lot like 2-Amino-5-trifluoromethylpyridine.
It’s tempting to treat all pyridine derivatives as interchangeable, but small changes dramatically alter both physical properties and chemical behavior. Take 2-aminopyridine, a staple intermediate in its own right. Dropping a trifluoromethyl group at the 5-position changes both electron distribution in the ring and steric profile. In practice, this means you get different reactivity toward coupling partners, a shift in metabolic fate inside biological systems, and altered solubility.
Compared to simple trifluoromethylpyridine, the amino group on ATP-2A5TFMP gives chemists that all-important handle for further functionalization. Trying to introduce an amino group through other, later-stage methods can get expensive and yield messy results. Here, the needed function is already baked in. It’s one of those rare cases where a “ready to use” product really means less time wrestling with protection and deprotection steps.
Users often compare protocols side-by-side, and there’s real savings—both in time and solvent—when switching from mixed precursors to a single, dual-functionalized building block. From my own experience, having a stable, crystalline powder that stays easy to handle during weighing, melting, and reaction setup is underrated in day-to-day lab work. Nobody wants to lose product to volatility or sublimation.
The gap between theory and application shows up fast in synthetic workflows. A chemist can spot trends after enough cycles: reactions that routinely fail or generate low yields almost always trace back to problems with the starting materials. ATP-2A5TFMP delivers on consistency, so the team spends less time troubleshooting and more time driving toward project milestones.
Switching to this compound from older, less specialized options often means better reproducibility. This is especially important in regulated settings, like pharmaceuticals or agrochemicals, where every batch needs to meet tough standards. Having a product with reliable documentation and batch records means less risk and more confidence at every scale, from lab bench to pilot plant to full manufacture.
From a safety perspective, the fluorinated aromatic structure typically provides lower volatility than non-fluorinated analogs. This translates into fewer headaches over emissions and easier air monitoring, especially in facilities keen to minimize worker exposure and environmental discharge.
It’s worth mentioning—since not all intermediates behave—handling ATP-2A5TFMP rarely involves surprises. No odd color changes, no sudden caking or awkward recrystallizations on the shelf, no sulfur stink or sticky residues on glassware. These are small details until they’re not, as anyone running nighttime reactor cycles or prepping scale-up batches will tell you.
In the education world, up-and-coming chemists learn early that a single misplaced group can derail weeks of planning. Choosing intermediates with both flexibility and stability helps reduce lab accidents and streamlines training. 2-Amino-5-trifluoromethylpyridine earns a place on the shelf for its reliability in core curriculum experiments as well as in advanced synthesis projects.
Industry values scale and reproducibility. Few things are more frustrating than having to tune every reaction whenever starting material sources change. Because ATP-2A5TFMP is synthesized to demanding purity standards, you don’t see the lot-to-lot variation or impurity headaches that complicate regulatory filings or slow down process development.
A shift toward “greener” chemistry reaches into every corner of today’s industry. Compounds that generate less waste, demand less harsh processing, or integrate well in one-pot syntheses win points. ATP-2A5TFMP, delivered in high purity, limits the need for extensive rework or extra purification—meaning more of each starting input ends up in the desired product, not in the waste barrel.
It’s not just hearsay—there’s a consistent trend in the open literature and patents highlighting the uptick in fluorinated intermediates in both pharma and agrochemical pipelines. The U.S. Food and Drug Administration and similar agencies have approved a growing number of drugs with trifluoromethyl and pyridine groups. An analysis published in Journal of Medicinal Chemistry points out that the trifluoromethyl group often brings metabolic stability and improved binding affinity, giving drug candidates a better shot in advanced trials.
In agricultural research, organizations like the International Union of Pure and Applied Chemistry have tracked increases in the use of fluorinated aromatics in new product registrations. The capacity of 2-Amino-5-trifluoromethylpyridine to serve as a precursor means it indirectly supports innovation across the board—new herbicides, fungicides, even certain plant growth regulators.
Prices for high-purity pyridine intermediates tend to reflect both their importance and the challenge of reliable production. While demand for ATP-2A5TFMP has climbed, market analytics show that better synthetic routes developed over the past decade have actually lowered costs and improved global access. This is a case where advances in catalysis, purification, and process monitoring directly benefit downstream users. Reduced cost barriers make it easier for even small startups and academic labs to take advantage of cutting-edge building blocks.
No compound comes without challenges. Over the years, questions about the environmental fate and impact of fluorinated chemicals have received serious attention. Regulatory agencies in the European Union, North America, and Asia closely monitor release and disposal. ATP-2A5TFMP is not immune to scrutiny. Process teams have to design waste streams to capture, recycle, or neutralize fluorine-containing byproducts, which means it’s essential to plan ahead.
In my own work with chemical compliance efforts, keeping step with evolving regulations is less of a burden when suppliers provide clear, up-to-date data on product traceability and toxicity. The fact that ATP-2A5TFMP earns a spot on procurement lists for so many firms is a sign that industry and academic partners regard its risk profile as manageable when handled with basic care.
Another barrier can be access in regions where import controls on raw materials or fine chemicals change year by year. International shipping of specialty intermediates sometimes causes delays or hiccups in project planning. Efforts to localize synthesis or partner with regional producers help sidestep these issues. Trusted supplier relationships and transparent sourcing information become even more important.
As innovation presses ahead, people working at the cutting edge keep finding new uses for compounds like 2-Amino-5-trifluoromethylpyridine. In pharma R&D, more screening is happening with AI tools, but the availability of robust, functionalized starting materials remains the key step that turns a theoretical molecule into a physical drug candidate. For every routine batch, there’s also an outlier—some breakthrough that comes when a chemist takes a chance on a less-explored route, made possible by a dependable intermediate.
I’ve seen process engineers work wonders by tweaking conditions for ATP-2A5TFMP-based reactions, reducing side-products and cutting cycle time. The right intermediate helps push greener chemistry goals too. With global pressure for sustainability and cost-shaving, high-purity, solid-state intermediates allow for more selective reactions, lower temperatures, and less solvent waste overall.
Collaboration between academic chemistry departments and industry often centers on how to make things like ATP-2A5TFMP more accessible, less costly, or greener. Efforts focus on flow chemistry, continuous processing, and bio-based routes. Every incremental gain here lends resilience to the supply chain and opens doors for smaller teams that need powerful tools without breaking the bank.
A lot of editorial commentary can sound overly technical, but the bottom line comes down to real-world results. Over years in the field, I’ve watched research projects derail because the right intermediate wasn’t available on time or in the right quality. ATP-2A5TFMP keeps ambitions alive for both seasoned professionals and newcomers at the bench. Reliable, well-characterized intermediates are the difference between “nice idea” and “publishable result” or between opportunity and missed deadline.
Anyone searching for the new frontier in fine chemicals, pharmaceuticals, or agriculture will cross paths with ATP-2A5TFMP, even if only as a stepping stone. In each setting, the balance it offers—between reactivity and stability, accessibility and performance—sets a standard that its relatives struggle to match. Working with this compound offers less hassle and more confidence. It doesn’t make headlines, but it often shapes the discoveries that do.
Looking at the broader landscape, real improvement comes from good partnerships—between suppliers and buyers, between regulatory bodies and innovators. Strong product stewardship around intermediates like 2-Amino-5-trifluoromethylpyridine keeps the focus on both progress and responsibility. Open data, honest assessment of environmental impact, and fair access all make a difference.
Sustainability goals shouldn’t force a retreat from important chemistries. Instead, they prompt smarter application and more thoughtful engineering. As more teams adopt ATP-2A5TFMP or similar tools, sharing best practices and publishing both successes and pitfalls helps everyone. Transparency and training—making sure users know what they’re handling and how—protect both people and projects.
From my own vantage point, the future for reliable, well-characterized intermediates looks strong, especially as products like ATP-2A5TFMP continue finding their way into ever more ambitious projects. That progress depends on connecting needs with solutions, keeping an eye on safety, and never losing sight of the practical realities that drive innovation in the lab and on the shop floor.
