|
HS Code |
740560 |
| Chemicalname | 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde |
| Casnumber | 24358-87-8 |
| Molecularformula | C9H8N2O |
| Molecularweight | 160.17 g/mol |
| Appearance | Solid (typically off-white to yellow powder) |
| Meltingpoint | 105-109°C |
| Boilingpoint | Unavailable or decomposes |
| Smiles | Cc1ccc2ncc(C=O)nc2c1 |
| Inchi | InChI=1S/C9H8N2O/c1-7-2-3-8-10-6-9(5-12)11-8(7)4-7/h2-6H,1H3 |
| Solubility | Slightly soluble in organic solvents such as DMSO and methanol |
As an accredited 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 5 grams, labeled with chemical name, CAS number, hazard symbols, lot number, and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde packed securely in drums, maximizing stability and safe international transport. |
| Shipping | 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde is shipped in a tightly sealed container, protected from light and moisture. It should be handled as a hazardous chemical, following all applicable regulations for transport, including labeling and documentation. Shipment may require temperature control and compliance with local, national, and international chemical safety standards. |
| Storage | 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizers. Protect from light and moisture. Store at room temperature or as recommended by the manufacturer, and ensure proper labeling and access control for laboratory chemicals. |
| Shelf Life | Shelf life of 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde is typically 2-3 years when stored cool, dry, and protected from light. |
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Purity 98%: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde with 98% purity is used in pharmaceutical intermediate synthesis, where high purity ensures optimal reaction yields and reduced by-product formation. Molecular weight 172.18 g/mol: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde at molecular weight 172.18 g/mol is used in chemical library development, where precise molecular mass enables accurate compound identification and library profiling. Melting point 102°C: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde with a melting point of 102°C is used in solid-phase organic synthesis, where defined thermal properties facilitate reproducible processing and purification. Particle size <50 µm: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde at particle size less than 50 µm is used in high-throughput screening protocols, where fine particle distribution enhances sample dissolution and assay consistency. Stability temperature up to 120°C: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde with stability up to 120°C is used in medicinal chemistry research, where thermal stability allows for robust synthesis under elevated conditions. Chromatographic grade: 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde of chromatographic grade is used in analytical method development, where high-grade quality ensures reliable quantification and purity analysis. |
Competitive 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde prices that fit your budget—flexible terms and customized quotes for every order.
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At our production facility, every batch of 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde comes from hands-on expertise and a thorough understanding of what our end-users face daily in R&D or manufacturing. Over the years, chemists and process engineers on our team have honed each step, from raw material selection to final purification. The story of this compound goes well beyond purity percentages or neat chemical synopses—the real tale lies in what happens behind the scenes and how users benefit from that attention to detail.
Our clients drive innovation across drug discovery, analytical research, and specialty synthesis. Working with pyridine derivatives like 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde demands predictability. Even a slight shift in impurity levels or moisture content can complicate a synthetic route or throw off a key analytical result. Staff in our labs learned years ago that meeting those needs requires close monitoring of every step—from monitored solvent handling to frequent testing at critical stages. Whether pouring a bottle in our blending room or checking chromatography plates for byproducts, we set up checks because one off result could mean hours of lost time in a partner’s project downstream.
Not every batch reaches the most stringent target. We reject material when an off-color or an unexpected UV spectrum shows up, long before it would ever hit a flask or GC-MS. That direct production oversight separates actual manufacturers from repackagers or middlemen who rarely see the full process. Customers have called us after struggling with a competitor’s lot that failed to dissolve or required extra purification. Sometimes they lose a week running an extra column; sometimes they give up on a crucial experiment. Once they try our batch, with clear TLC spots and a sharp melting range, the hassle disappears. Getting there took years of on-the-ground adjustments, not just a reliance on equipment calibration certificates or routine analysis reports.
Ask anyone on our crew about the frustrating early years. No two syntheses ran identically. We recognized the value of slow addition of reactants under nitrogen, or why glassware free of even trace acidic residues prevented side reactions. Operators tweak stirring speeds or solvent volumes based on what actually comes out of the flask, not only what the procedure says ‘should’ happen. As a manufacturer, we see where theoretical chemistry collides with daily realities: ambient humidity, batch-to-batch substrate variability, or the true shelf life under warehouse lights. Those insights fill the knowledge gaps left by data sheets alone. Customers rarely call us about routine supply—they call us when something unexpected comes up and they know we keep actual notebooks of experiments, not just computer logs.
Pyridine chemistry in particular rewards the detail-oriented. Imidazo ring systems react unpredictably under some conditions, especially when handling aldehyde groups. During scale-ups, our team refined crystallization temperatures, distilled solvents twice, swapped stir bar coatings, and checked trace metal content, all based on real failures and wins. These choices helped us minimize side products such as N-oxide formation or over-reduction—pitfalls that academic procedures usually understate. When talking with clients in pharma or material science, our staff can speak to the subtle color difference that reveals a pure batch versus one that risks project delays.
Many buyers start with catalog numbers or synonyms, but innovation comes from molecular details. In our facility, ‘model’ refers to more than a SKU or label; it means a specific set of physical and chemical traits achieved through repeatable process decisions. Unlike some intermediates on offer elsewhere, our batches reach customers with low residual solvents and well-characterized impurity profiles. We don’t pursue unwarranted claims about analytical figures unless we can show original, in-house chromatograms. That credibility does not develop overnight, but from a factory where a team stands behind every drum and bottle shipped to a researcher’s bench.
Some properties deserve special focus: moisture tolerance, reactivity towards nucleophiles, and stability during storage. Early on, we realized how aldehyde-containing pyridines degrade if packaging breathes or if desiccants go missing. That experience led us to reinforce container seals, shorten transit time windows, and offer personal storage advice to users. Years later, clients still report that our compound retains its recognizable pale yellow hue and doesn’t degrade or yellow after a few weeks under proper conditions. The warehouse team, alongside QA, meticulously checks inventory rotation—no batch gets shipped past its prime, eliminating the risk of handling unpredictable material on the client’s bench top.
Many of our conversations begin with application-driven requests. A pharmaceutical partner may be exploring heterocyclic building blocks in kinase inhibitor projects, or an academic lab might chase a novel fluorescent probe. Some applications require extended reaction runs or post-reaction isolations, where byproduct content quickly becomes apparent. We learned to tailor purification steps, sometimes taking hit on overall yield, to meet these particular goals. Satisfying those stringent requirements resulted from years immersed in the manufacturing process, learning when a tweak on temperature, time, or reagent addition could push a product from ‘fit for catalog’ to ‘fit for critical research.’
Imidazo[1,2-a]pyridine scaffolds underpin biologically active molecules and specialty ligands. The carbaldehyde group at position 3 offers synthetic flexibility. Our team regularly takes calls from chemists working on intermediate scale-up, double substitutions, or functional group transformations. These users appreciate not only the consistent melting range and NMR trace but also advice about side reactions they might encounter based on our archived batch notes. The collective knowledge stored after each successful or failed synthesis—sometimes jotted on the back of a glove or in the margin of a batch record—proves more useful than a dozen copied spectra from a literature review.
Even now, our technical support team, many of whom contributed to early-process refinement, fields regular queries about solubility in odd binary solvents or conditions for selective condensation. Some clients seek pointers for downstream derivatization; others want to know the logic behind our crystallization solvent. Details like hygroscopic behavior or tolerance to basic reagents become differentiators. Those details don’t show up in catalog pages, but they matter during application—where expectations, costs, and deadlines converge.
Comparisons with other products reveal a few key differences. Standard chemical suppliers rarely maintain batch-level control from raw material to finished compound. Distributors often store stock at ambient temperatures with little insight into age or precursor origin. Our operation keeps direct traceability, so each customer request ties back to a real production log. This means when a jar’s sealed at our end, the exact route, conditions, and raw materials are documented—never left to chance or assumption by third parties.
We keep all analytical work in-house, using calibrated GC-MS, NMR, and independent cross-verification by experienced staff, not by rotating interns. That means real continuity when someone follows up about subtle shifts in UV absorbance or IR spectra. Over time, those incremental quality assurances build trust. We’ve witnessed situations where a national lab’s project failed twice using commercial stock, only to see progress resume after switching to our batch. In that scenario, the victory stemmed from years of vigilance around trace water exclusion and hand-checked glassware—details invisible from a standard product listing. Most resellers lack such insights since they repackage and resell on behalf of upstream producers, rarely interacting with the real chemistry or ever seeing the consequences of a subpar sample.
Many intermediates on the market display variability, stemming partly from inconsistent precursor supply and partly from rapid regional reselling leading to storage in uncontrolled conditions. By building long-standing relationships with the original raw material manufacturers—sometimes even assisting in process troubleshooting—we help ensure more uniform input for our synthesis, ultimately reducing variability batch-to-batch. Customers encounter fewer unwanted delays, because the same team prepares, packages, and tests each delivery.
Our team remembers batches stuck at the filtration step, entire runs halted due to trace contamination or container failure, or QA interventions to correct analytical misreads. Each hiccup left us with lessons that books and journals gloss over. Over time, thorough root-cause analyses reduced those issues. Consistency, in our hands, occurs not due to rigid paperwork but because experienced operators genuinely learn which details result in desirable outcomes—and share those lessons across production shifts.
Direct manufacturing brings challenges. Environmental differences in each region, varying infrastructure ages, and the unpredictability of material logistics force adaptability. Our operators adjust for warehouse climate variation or transport lag by sealing containers better or double-wrapping sensitive lots. Each new infrastructure upgrade or vendor shift prompts a team huddle to update batch workflows, not just paperwork. By carrying the risks, and seeing the real-life effect on both outcome and bottom line, we have the flexibility and discipline needed to offer a compound that can be trusted at a critical project stage.
We keep open lines of communication with R&D and production partners. Every reported anomaly—an unusual color, an unexplained WT% shift, a failed synthesis—receives thorough investigation. In some cases, a customer points out a solubility issue, prompting a review of storage humidity or solvent carryover in our facility. Once, a collaborator highlighted trouble with a particular downstream amination. Our chemists and analysts dug into archive records, tested multiple variants, and suggested alternate stock to circumvent the specific challenge. The ability to offer real troubleshooting, not just a template apology, comes directly from years of hands-on synthesis and process ownership.
In a recent example, an advanced materials group faced clogging in a continuous flow setup. Our application support dug into their flow rates and proposed a minor grind size adjustment, paired with modified shipment packaging. The group completed their pilot run on schedule, without repeated troubleshooting. Lessons from such practical challenges cycle back into our batch protocols, preserving both our scientific integrity and our partners’ productivity.
Every person in our organization, from synthesis operator to product support chemist, holds practical knowledge about 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde that only comes with sustained hands-on experience. The line between process owner and technical adviser blurs, because both roles demand close attention to product performance and real-world feedback. Unforeseen bottlenecks in synthesis, or user-identified anomalies, shape our future process guidelines. That loop of hands-on insights (and occasionally hard-won troubleshooting) creates value, not just for internal teams but also for those using our products under tough project timelines.
We’ve noticed that most users want suppliers who stand ready to share lessons from years of direct synthesis, not just suppliers peddling a product through intermediaries. Building that kind of trust took years. Taking responsibility for each gram produced means dealing with the full complexity inherent in specialty building blocks—without shifting the burden to end users. In practice, every upgrade in our workflow, every user call answered by a skilled chemist instead of a call center tech, shows the difference between points of contact with actual manufacturing experience versus scripts or forwarding addresses.
For researchers and process chemists, lost days due to inconsistent materials can set development or publication timelines back months. Our approach blends high-grade synthetic chemistry with practical, boots-on-the-ground problem solving. Fielding a crystal-clear sample with reliable spectral markers and minimal variance helps users push projects forward. Each refinement—tracking solvent residuals, investing in reliable packaging, or tweaking filtration steps—eliminates unnecessary repetition in downstream labs. The value doesn’t come solely from achieving a particular purity threshold but from empowering users to get predictable results, save precious resources, and advance quickly.
No single factor defines high-quality 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde. Experience in synthesis, targeted purification, focus on physical integrity, and responsiveness to user requirements all matter. Having a team that can troubleshoot odd issues—not just respond with scripted answers—brings peace of mind when researchers face crucial milestones. Each day, users count on our willingness to field inquiries about compatibility, solubility, and performance, knowing that every answer reflects direct encounters with the substance, not hypothetical best practices.
Our mission in offering 7-Methylimidazo[1,2-a]pyridine-3-carbaldehyde grows stronger with every batch. We draw on decades of shared insights to support the innovators who rely on this compound for their breakthroughs. Focusing on real-world issues and solutions, we keep improving everything from raw material qualification to technical support. As new challenges arise within user projects—scaling reactions, addressing new regulatory demands, supporting emerging fields—our production team remains within reach, ready to adapt to the next set of needs.
We value robust partnerships with every user, whether advancing pharmaceutical research, creating next-generation functional materials, or training the next wave of chemists. Our commitment carries through every aspect that users can’t see in a catalog or spec sheet—the curation of each lot, the absence of batch-to-batch surprises, and the readiness to step in with firsthand advice shaped by true manufacturing knowledge.
