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HS Code |
786264 |
| Iupac Name | 6-methyl-2-(4-methylphenyl)imidazo[1,2-a]pyridine-3-amine |
| Molecular Formula | C15H15N3 |
| Molar Mass | 237.3 g/mol |
| Cas Number | 590371-15-2 |
| Appearance | off-white to light yellow solid |
| Melting Point | 168-172°C |
| Solubility In Water | low |
| Smiles | Cc1ccc(cc1)c2nc3c(n2)cc(C)cc3N |
| Inchi | InChI=1S/C15H15N3/c1-10-4-6-12(7-5-10)15-16-13-8-3-11(2)9-14(13)18-15/h4-9H,1-3H3,(H2,16,18) |
| Logp | estimated ~2.7 |
| Purity | typically >98% (commercial samples) |
| Storage Conditions | store at room temperature, dry, away from light |
As an accredited 6-METHYL-2-(4-METHYLPHENYL)- IMIDAZO{1,2-A}PYRIDINE-3- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging is a sealed amber glass vial containing 5 grams of 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO[1,2-A]PYRIDINE-3-, labeled for laboratory use. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- in sealed drums/pallets, optimizing space and ensuring safe transport. |
| Shipping | The chemical **6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO[1,2-A]PYRIDINE-3-** is shipped in a tightly sealed container, compliant with regulatory guidelines for hazardous materials. It is packaged with absorbent material, clearly labeled, and protected from light and moisture. Shipping adheres to all applicable chemical transport regulations to ensure safety and integrity during transit. |
| Storage | **Storage of 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO[1,2-A]PYRIDINE-3-**: Store the compound in a tightly sealed container, protected from light and moisture. Keep at room temperature, preferably in a cool, dry, and well-ventilated area away from incompatible materials such as strong oxidizing agents. Follow standard laboratory safety protocols and store according to local regulations for chemical substances. |
| Shelf Life | Shelf life: Store 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO[1,2-A]PYRIDINE-3- in a cool, dry place; stable for 2 years. |
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Purity 98%: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield formation of target heterocyclic compounds. Melting Point 210°C: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with a melting point of 210°C is used in high-temperature solid-state reactions, where it improves processing consistency. Molecular Weight 247.30 g/mol: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with a molecular weight of 247.30 g/mol is used in analytical reference standards, where it delivers accurate mass spectrometric calibration. Solubility in DMSO: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with high solubility in DMSO is used in bioassay development, where it enables consistent compound dosing. Stability Temperature 50°C: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with a stability temperature of 50°C is used in storage and formulation studies, where it ensures chemical integrity during accelerated aging tests. Particle Size <20 μm: 6-METHYL-2-(4-METHYLPHENYL)-IMIDAZO{1,2-A}PYRIDINE-3- with a particle size below 20 micrometers is used in tablet manufacturing, where it provides uniform distribution and enhances dissolution rates. |
Competitive 6-METHYL-2-(4-METHYLPHENYL)- IMIDAZO{1,2-A}PYRIDINE-3- 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@boxa-chem.com.
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Tel: +8615371019725
Email: sales7@boxa-chem.com
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In our facility, we do more than combine standard reactants and ship out drums. Chemical science requires patience and purpose. Through years of process optimization, we found that imidazopyridine-based molecules were gaining traction for their unique structural characteristics. 6-Methyl-2-(4-methylphenyl)-imidazo{1,2-a}pyridine-3- emerged from this environment of practical curiosity.
We noticed a shift among formulation chemists—both in research and industrial production—toward the use of heterocyclic scaffolds that carry both methyl and phenyl substitutions. This trend stems from a need for greater selectivity and predictable reactivity in target-oriented synthesis. For those of us on the manufacturing floor, that means carefully designing operations for regioselectivity, controlling moisture and air, and perfecting purification steps. During early production runs, we observed this compound’s stability in ambient storage conditions, which saved significant resources and kept drum inventories moving.
Instead of chasing flashy branding or wrapping our product in buzzwords, we focus on hard outcomes. This product undergoes multiple purity assessments through gas chromatography and HPLC, allowing us to target reproducible purities above 99%. Over years of scaling reactions, we’ve dialed in parameters like solvent selection and temperature ramps to minimize side products, which helps customers in downstream applications avoid byproduct complications. Every batch starts with freshly sourced raw materials, minimizing trace impurity buildup. Consistency isn’t an afterthought—it’s a byproduct of repeatable, controlled steps and operators who know exactly which signals to watch in each reaction stage.
Filtering and drying bring their own set of headaches, especially as batch size grows. Filtering these crystals while preventing dust contamination takes ongoing investment in sealed handling and validated cleaning of every surface. Our drying schedule ensures that the powder meets low residual solvent requirements without scorching or introducing variable cake thickness. At this stage, any slip-up means discarded production or out-of-spec product. Never have we released this material without confirming melting point and detailed spectral conformity, since one off-note could alter a customer’s experiment or a pilot batch scenario.
Many researchers and process chemists ask about the differences between 6-methyl-2-(4-methylphenyl)-imidazo{1,2-a}pyridine-3- and more commonly available analogs. The difference is not just academic. Substituent placement defines both the reactivity and utility in downstream products. For instance, the 4-methylphenyl group helps tune electronic properties and steric profile, compared to unsubstituted or ortho-substituted analogs. Our team has checked side-by-side syntheses using similar imidazopyridines, often observing increased yields and high crystallinity with our specific molecular design.
Customers synthesizing intermediates for pharmaceutical or agrochemical applications benefit from this improved handling. We’ve recorded lower decomposition on heating and straightforward recrystallization—a practical advantage for pilot or scale-up teams who spend countless hours debugging crystallization steps. Other aromatic heterocycles sometimes carry unpredictable isomerization or color changes; here, you’ll notice that our batches hold a uniform appearance between runs, a result of our tight parameter controls from bench to metric ton scale.
Chemical products often get described as shelf-stable or robust without meaningful backup. Our approach is rooted in what our outbound teams witness in warehouses around the world. Age or temperature extremes can still interfere, especially with nitrogen-sensitive compounds, but we track container histories with careful lot date records. Barrel surfaces are cleaned between fills using validated protocols, and secondary containment is provided for international shipments. We’ve had situations where temperature excursions occurred mid-transit; because of built-in stability, the final product quality didn’t falter. Our technical support documents recommend practical storage and desiccant use based on actual product history, not just a theoretical risk table.
End users sometimes call us to ask about caking or flow changes after several months of storage. In our experience, 6-methyl-2-(4-methylphenyl)-imidazo{1,2-a}pyridine-3- remains free-flowing provided it stays sealed in original packaging. Those working in large-scale settings appreciate the time this saves during weigh-outs and transfers—avoiding hours regrinding compacted solids or chasing static issues.
It’s easy to emphasize technical specs, but productivity carries just as much weight. By manufacturing this compound within a facility where all stages from synthesis to isolation are managed under one roof, we cut lead times and maintain traceability. Labs and factories can plan their schedules more predictably.
Our team collaborates directly with several R&D labs in need of immediate troubleshooting—whether it’s reactivity consistency, impurity profile, or just getting a uniform sample across multiple kilo packages. Getting a repeatable reaction or a consistent analytical signal makes the difference when scaling from gram to kilogram. If a batch ever falls short, we isolate the root cause by examining solvent consistency, stirring integrity, or even the calibration of monitoring equipment.
Unlike generic traders who may switch supply origin with each shipment, we commit to uninterrupted process sequences. Steady supply avoids the kind of sudden surprises that leave project timelines hanging or cause regulatory paperwork delays. Our product offers more than just a chemical compound—it provides logistical and operational reliability.
Realizing the best outcomes for our customers means grasping what chemists face in their day-to-day work. From small academic labs to multinational corporations, a common complaint we hear relates to unpredictable deliveries, packaging failures, and purity slip-ups. We developed a robust quality management system attentive to these complaints—no batch ships without document verification, and every lot receives feedback tracking from end users.
In several pilot projects, customers have documented increased throughput and fewer process slowdowns after switching from generic sources to our material. That’s because we handle every shipment with real consequences in mind: lost days of work and capital are far more costly than one-off price negotiations. Years of working with varied users taught us to avoid the kind of shortcuts that force people to recalculate their reactions or run extra purifications.
Our experience shows that even minor packaging upgrades translate into measurable savings at the site level. Whether it’s resealable drums or multi-layer bags, every design change gets field-tested before widespread use. We welcome site visits and technical audits, which continue to drive internal process improvements rather than hinder them.
In chemical manufacturing, perfection in every batch remains an ideal rather than a daily reality. Supply interruptions, raw material variability, and new compliance rules keep us alert. Our production teams constantly review historical batch data to spot early warning signals. Some years ago, we dealt with an upstream shortage of key building blocks. Instead of seeking alternative quality shortcuts that might harm downstream performance, we established secondary supply relationships and increased auditing of each lot.
During peak demand, lead times tighten and production lines stretch. Our on-site inventory management pulls on years of pattern recognition to ensure that bottlenecks do not snowball. For critical customers, pre-allocation of finished goods—rather than a rolling waitlist—builds reliability into each contract. We never over-promise; if a weather event threatens shipping, we communicate the risk and propose alternatives proactively, not after the fact.
Waste management also deserves attention. Efficient capture and treatment of mother liquors, spent solvents, and filtration residues receive weekly review by our safety and technical teams. Closed-loop solvent recovery, undertaken on-site, cuts both environmental impact and cost, an advantage that customers recognize when reviewing sustainability audits.
Years of practice taught us the true cost of inconsistency. Research, pilot, and large-scale synthesis all depend on stable starting materials. With 6-methyl-2-(4-methylphenyl)-imidazo{1,2-a}pyridine-3-, we built a product driven by both bench experience and scaled manufacturing discipline. The molecular design caters to specificity—offering better yield, manageable handling, and minimal degradation under correct conditions.
This qualitative value often exceeds what standardized product sheets reveal. Customers report smoother process performance, fewer interruptions, and confidence during scale-up stages. In scenarios demanding tailored applications—such as stepwise functionalization or library synthesis—our material proves adaptable and predictable.
Repeat users highlight the convenience of working with a supplier who controls every process step and stands behind each container shipped. Not every customer needs advanced documentation, but when regulatory or analytical needs arise, we ensure certificates and supporting data are readily provided. This approach closes the gap between bench reliability and warehouse scale, reducing the need for in-house analytical retesting among our partners.
We rarely stand still. Each season, our pilot area welcomes feedback from both the factory floor and customer sites. One example: an earlier generation of this compound showed flowability problems in high-humidity regions. Armed with actual end-user feedback, our teams worked through drying protocols and packaging improvements until the problem disappeared in subsequent batches. Stories like this reinforce why every step in the chain matters—from raw input purity to final drum labeling.
Chemistry doesn’t reward complacency. We constantly invest in upgraded monitoring, better staff training, and updated analytical tools. We don’t buy certifications for their own sake; we expect our process standards to hold up under close review by any client with technical rigor. If a process step creates unnecessary cost or risk, we revisit it. By learning directly from our customers, whether they’re running single flasks or kilo-scale reactors, we keep improving every batch and shipment.
The research environment for heterocyclic building blocks continues to expand, especially in areas connected to pharmaceuticals, specialty polymers, and agricultural chemical innovation. As more enterprises look to bridge the lab-to-facility gap, readily available high-purity starting materials have become a cornerstone for process reliability. Early collaborations with biotech and discovery-focused firms allow us to anticipate trends and optimize product characteristics accordingly.
For syntheses that explore new derivatives or molecular scaffolds, this compound provides a robust foundation. Several ongoing projects leverage its stability and functional group compatibility in carbon–carbon and heteroatom coupling reactions. Analytical teams report low impurity carryover and resilience against storage-related degradation—cutting down the build-up of trace side products that complicate research progress.
Chemical supply comes down to trust. By acting as manufacturers, not repackagers, we take direct responsibility. That responsibility comes from hands-on work—tracking every material in the tank farm, logging every stirrer and filter entry, running periodic checks on every vessel and packaging station. We don’t rely solely on automated alerts; our crews have the experience to spot issues before they multiply.
As new challenges emerge—stricter compliance norms, unpredictable supply chain disruptions, and the pressure for ever-lower impurities—our response remains practical. Every year, we reinvest in our teams, systems, and plant to address the realities facing chemical users: steady access, dependable quality, and honest support during both peaks and valleys of the development cycle. The feedback loop from customer site to plant floor remains our best resource in keeping 6-methyl-2-(4-methylphenyl)-imidazo{1,2-a}pyridine-3- a reliable pillar in both industrial and research supply chains.
Direct experience anchors our approach. We pursue process improvements and technical upgrades not for show but because each change reduces frustration for our partners in the field. Transparent production, traceable batches, and a willingness to troubleshoot in real-time combine to offer something more substantial than standardized product offerings. That’s the point of our work—delivering real value to people counting on quality material, every drum, every time.
