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HS Code |
940228 |
| Chemical Name | Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile |
| Molecular Formula | C13H6BrFN4 |
| Molecular Weight | 329.12 g/mol |
| Cas Number | 1441146-57-1 |
| Appearance | Solid |
| Purity | Typically ≥98% |
| Solubility | Soluble in DMSO, DMF |
| Storage Temperature | 2-8°C |
| Smiles | C1=CC(=NC=C1C2=NN3C=CC(Br)=C3C2C#N)F |
| Inchi Key | APNBOXDFVIKKSB-UHFFFAOYSA-N |
| Synonyms | None reported |
| Applications | Research, intermediate in synthesis |
As an accredited Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass vial containing 1 gram of Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile with tamper-evident seal. |
| Container Loading (20′ FCL) | 20′ FCL container loaded with securely packed drums or bags of Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile. |
| Shipping | This chemical, Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile, is shipped in compliance with relevant hazardous materials regulations. It is securely sealed in airtight, chemically resistant containers, cushioned to prevent breakage, and packed with appropriate labeling and documentation to ensure safe transport and handling. Temperature and light exposure may be controlled as required. |
| Storage | Store **Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile** in a tightly sealed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Keep away from incompatible materials such as strong oxidizers and acids. Handle under inert atmosphere if sensitive to air. Label clearly and store in accordance with relevant chemical safety protocols and local regulations. |
| Shelf Life | Shelf life: Stable for at least 2 years when stored tightly sealed at 2-8°C, protected from light and moisture. |
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Purity 98%: Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile with 98% purity is used in pharmaceutical intermediate synthesis, where high-purity ensures optimal compound yield and minimal byproduct formation. Molecular weight 314.12 g/mol: Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile at 314.12 g/mol is used in lead optimization for drug discovery, where defined molecular weight supports accurate formulation and dosage calculations. Melting point 182°C: Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile with a melting point of 182°C is used in solid-state compound screening, where thermal stability allows safe processing and storage. Stability temperature up to 120°C: Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile with stability up to 120°C is used in high-temperature reaction protocols, where thermal endurance ensures compound integrity during synthesis. Particle size <10 μm: Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile with a particle size less than 10 μm is used in formulation of analytical standards, where fine particle distribution enhances solubility and homogeneous dispersion. |
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Working hands-on with Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile offers daily reminders of chemistry’s practical power. Every batch that leaves our reactor stands for a blend of meticulous synthesis and disciplined process control. The structure itself, with its pyridinyl and pyrazolopyridine backbone hooked to a bromo group and a fluoro substituent, shows up in research discussions where new molecular entities lay the foundation for pharmaceuticals, crop protection, and advanced materials.
From our side of the bench, developing this product wasn’t just about stitching together rare heterocycles. It took persistent refining—nailing down purification steps that handle pyridine impurities, tuning temperature ramps during cyclization, and building up reproducibility in our nucleophilic substitution protocol. Over years, these daily technical puzzles shaped a product that now fits into challenging discovery campaigns and scale-up programs with confidence. Chemists trust this material to perform without surprises under their reaction conditions, whether screening library members or advancing toward pilot scale.
Conversations about this compound rarely last long before analytical rigor comes up. We hear direct requests for HPLC chromatograms and NMR overlays to prove identity and purity. Real-world projects depend on reliable feeds, so we keep batch records tight and document test results using international standards. Our team knows that being able to guarantee a consistent assay percentage and minimal levels of isomeric or process impurities makes the difference between project acceleration and troubleshooting dead ends.
Keeping water content low, knocking down residual solvents below detection, and providing detailed spectral data reflects how chemical manufacturing transcends simple mixing or reaction. Our SOPs tie purity controls to actual process parameters—not just paper claims. Customers often remember the time their own team’s syntheses stalled from off-spec materials. Making sure our product doesn’t introduce such risk demands hands-on vigilance from raw material checks to the packed, sealed final drum.
We don’t send out generic lots differentiated only by catalog numbers. Our approach rests on reproducible syntheses and full traceability. Every lot’s COA matches lab readings, so that each customer takes delivery with a sense of continuity and trust. If data points stray or a curve doesn’t match the validated pattern, it means holding back shipment—our manufacturing team stands behind every gram and kilo that bears our label.
Demand for Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile comes from several directions. Medicinal chemists in drug discovery tackle unexplored mechanisms and need robust building blocks for lead expansion. The pyridinyl and pyrazolopyridine core, spiked with a strategic bromo and fluoro, opens doors for synthetic elaboration at multiple positions. Functionalization options make it possible to try out new analogs with targeted activity, sidestepping bottlenecks found with more rigid aromatic scaffolds.
Agrochemical research calls for molecules ready to slot into SAR investigations and tune selectivity profiles. This compound’s unique structure can shift biological activity in crop protection screens, and formulation teams count on predictable stability during development. Academic teams running catalytic studies grab this material since the bromo handle supports cross-coupling platforms like Suzuki, Buchwald-Hartwig, and Negishi reactions—paving the way for libraries that move straight from reaction bench to biological assay.
Synthetic methodology researchers often look for substrates sensitive enough to challenge new catalysts, but stable enough to handle air, moisture, and standard workup. In our own lab, we’ve watched this compound perform solidly through repeated trials—holding up in glovebox-free environments and showing shelf-life that matches our real-time stability programs.
Plenty of bromo-pyridine and fluoropyridinyl derivatives line up in catalogs, but experience shows that one-size-fits-all rarely delivers for advanced applications. What sets Bromo-4-(6-fluoro-3-pyridinyl)-pyrazolo[1,5-a]pyridine-3-carbonitrile apart is a product of both its molecular structure and the way we manufacture it. The fluoro substituent on the pyridine ring pulls electronic density, shifting both reactivity and biological properties compared to its non-fluorinated siblings. The fused pyrazolo[1,5-a]pyridine adds rigidity and new faces for interaction, opening up binding modes rarely tapped by simple bromo-pyridines or benzenes.
In real projects, these differences change outcomes. Pharmaceutical teams aiming for kinase inhibitor libraries report increased selectivity when swapping in fused heterocycles with electron-withdrawing substituents. Process chemists stress less over purification when byproducts from our syntheses show distinct chromatographic separation, unlike the overlap seen with some competing intermediates. Users frequently notice that our product dissolves in standard polar solvents without forming inconvenient gels or precipitates mid-reaction—part of the benefit of batch control and attention to crystallinity.
Requests for custom particle size, alternate packing, or documentation to support DMF filings don’t go unanswered. Years spent optimizing this and similar molecules means we anticipate the technical questions and regulatory documentation that move a promising compound into actual production environments. Compared to commodity heterocycles, we make upgrades real for those pushing for faster project starts or smoother handoffs between R&D and scale-up.
Making this compound is as much about managing the practical realities of plant chemistry as it is about keeping up with literature. Sourcing high-purity starting materials, controlling moisture during organometallic steps, and troubleshooting minor byproduct formation demand a blend of experience and preparation. Late-night moments in the plant taught our team how a simple temperature fluctuation during cyclization can double impurity levels, or how using unverified oxidizers can throw off reproducibility batch to batch.
Close ties between plant chemists and our analytical group pay dividends. By sharing inline spectroscopic feedback and immediate chromatographic checks, we cut cycle times down and catch small excursions early. Manual oversight sometimes beats automation—especially for steps where exotherms or delayed precipitation can put both quality and safety at risk. The end goal is always to ensure every unit packed in drums or bottles gives runoff reactions the same profile batch after batch, whether the user is working at milligram or multi-gram scales.
Tracing every batch from raw material intake to final QC certification gives us a practical edge. If a client reanalyzes product and points out an inconsistency, we walk line-by-line through batch data to figure out where the deviation crept in. These lessons loop back to the next day’s production, tightening the process and keeping future lots consistent. Our organization’s culture rewards those who recognize and flag potential variances before they hit our customers’ benches.
We operate in a market where regulatory tightening is a daily reality. Projects targeting new therapeutic candidates or patented crop protection compounds mean customers want the full picture—not just a label on a drum. Traceability isn’t an afterthought for us, it’s built into each production cycle. Every run logs raw batch input, stepwise process specs, in-process monitoring, and final analytical signoff. No claims made on paper without proof in the batch records. Years of auditing by clients and regulatory authorities have burned into us what real compliance means.
Traceable, transparent manufacturing isn’t only risk mitigation. The value shows up in customer projects that move quickly from feasibility to preclinical or early field trial phases. Product deviations slow everyone down; rigorous documentation keeps projects moving. In our experience, the cost of retrofitting traceability or reconciling missing chain-of-custody far exceeds the up-front investment in integrated quality systems and real-time tracking. Our audit-ready approach results in fewer project setbacks and stronger client relationships.
Chemists and formulation scientists rely on the materials we produce not just for reliability, but as springboards for innovation. The fused-core, bromo-fluorinated structure of this compound turns standard cross-coupling into an open field for new analog design. Innovation at this level means customers can shortcut months off their screening timelines, stripping away routine troubleshooting about inconsistent starting materials.
We see teams in pharma and crop sciences leveraging this compound’s unique reactivity profile to reach challenging chemical space—scaffolds more rigid or more electron-deficient than classic pyridines. For academics, having a well-characterized standard lets them focus on hypothesis-driven science, using our material as a probe or test substrate in new transformations. The compound stands up well to routine storage and shipment, so research schedules stay on track rather than bogged down by degradation worries.
Scaling up this molecule wasn’t a one-shot deal. Each increase in batch size forced a re-examination of solvent, agitation, and workup. Unexpected fouling, rise in byproduct traces, or crystal habits led us to iterate reactor setups and cleaning procedures. Small pilot runs sometimes looked perfect, only to reveal new wrinkles at commercial scale—stirring power, UV exposure, filtration effect on particle size, and solvent recovery rates all came into focus.
Our technical team keeps direct lines open between plant production, process R&D, and QA/QC. If our analytical chemists spot odd peak shifts or baseline noise, it triggers a root-cause session—not just patchwork fixes. These habits, earned through years of working high-complexity chemistries, give confidence to end users who need lot-to-lot reproducibility. Customers who visit our site often point out the difference between manufacturers that scale standard pyridines and those who master more nuanced, functionalized heterocycles.
Retention of know-how, especially lessons from troubleshooting nuanced heterocycle synthesis, requires deliberate effort. Senior operators train new team members through real production shifts, highlighting subtle but critical inflection points—when foam threatens during workup, or how to tell if a vacuum filtration is pulling through desired product or unknown amorphous residue. These daily examples transform the abstract into the practical, so that knowledge accumulates instead of dissipating with personnel changes.
Every single operator who’s spent years running this process carries hard-won tips for safer and more consistent production. These stories, shared over routine meetings or during hands-on cleanup, remind us that even with automation and data tracking, human skill keeps processes stable. Customers sometimes ask for direct troubleshooting support; our ability to give credible, quick recommendations flows from this grassroots process expertise.
Chemical manufacturing stories too often overlook practical sourcing realities. Secure access to reliable raw materials underpins every downstream batch. For this particular product, we qualify suppliers not purely by price but by track records in consistency and transparency. Disruptions in the global supply chain—shortages, shipment delays, regulatory bottlenecks—test these supplier relationships and highlight the importance of local know-how.
Conscious steps to lower waste and energy consumption tie directly into our manufacturing practices. Process intensification, solvent minimization, and waste reclamation are not abstract commitments—they cut operating costs and reduce regulatory headaches down the road. Teams who stand over reactors, optimizing cycle times and filtration efficiencies, see these benefits firsthand. We spot sustainability boosts every day in recovered solvents or improved work-up protocols, which cut down both on environmental footprint and total production time.
Markets driven by high-value research and development set a high quality bar. Regulatory expectations bring up questions about impurity profiling, batch homogeneity, and documentation trail. We take direct responsibility for aligning with global standards—not by simply adhering to checklists, but by daily review of process steps, intermediate checks, and final packaging reviews that ensure standards are actually met on the ground.
New regulatory frameworks often demand additional data sets. Instead of scrambling, we prepare these in parallel with routine batch records, so that supporting analytical methods, synthetic pathways, or reference standards are ready when requested. It’s often the difference between approval delays and greenlights for scaling up.
Users remember not just the molecule, but the reliability of its supply and the transparency of the team supporting it. Our operating model builds on ongoing conversations—early signals about demand, real-time communication about production schedules, and honest updates when supply chain hiccups or equipment upgrades change timelines. By keeping the line open, we provide practical support during the crunch points of research projects.
Whether supporting bulk shipments to a pilot plant or providing small-volume samples for early validation, our manufacturing team aims for the same outcome: predictable, high-quality material, coupled with direct lines of technical support. We answer to the scientist who stakes project timelines and data integrity on each delivery. Through technical depth, careful process control, and daily teamwork, our manufacturing operation delivers more than just a compound—it backs every gram with expertise earned from real-world manufacture.
