|
HS Code |
147195 |
| Product Name | 6-(Hydroxymethyl)imidazo[1,2-a]pyridine |
| Purity | 97% |
| Chemical Formula | C8H8N2O |
| Molecular Weight | 148.16 g/mol |
| Cas Number | 223369-25-1 |
| Appearance | Off-white to beige solid |
| Melting Point | 79-83°C |
| Solubility | Soluble in DMSO, DMF, and methanol |
| Smiles | OCc1ccc2nccc2n1 |
| Storage Conditions | Store at 2-8°C, tightly sealed |
| Synonyms | 6-(Hydroxymethyl)imidazo[1,2-a]pyridine |
| Ec Number | None assigned |
As an accredited 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% 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 of 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97%, sealed with PTFE-lined cap, labeled for laboratory use. |
| Container Loading (20′ FCL) | 20’ FCL packed with sealed drums of 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97%; moisture-protected, labeled, compliant with transport regulations. |
| Shipping | 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is shipped in tightly sealed, chemical-resistant containers to prevent moisture and contamination. Packaging complies with safety regulations for hazardous materials. The shipment includes appropriate labeling and documentation. During transit, the chemical is protected from extreme temperatures and direct sunlight to ensure product integrity and safety. |
| Storage | Store 6-(Hydroxymethyl)imidazo[1,2-a]pyridine (97%) in a tightly sealed container, in a cool, dry, and well-ventilated area. Keep away from heat, sources of ignition, and direct sunlight. Protect from moisture and incompatible materials such as strong oxidizers. Store at room temperature unless otherwise specified by the manufacturer. Ensure proper labeling and access only to trained personnel. |
| Shelf Life | Shelf life: **2 years** when stored in a tightly sealed container at 2-8°C, protected from light and moisture. |
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Purity: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in heterocyclic compound synthesis, where high purity ensures reproducible reaction outcomes. Stability: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in pharmaceutical intermediate production, where excellent stability enhances shelf-life and process reliability. Melting Point: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in analytical research applications, where its defined melting point facilitates accurate compound identification. Particle Size: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in fine chemical formulations, where controlled particle size improves dissolution and formulation homogeneity. Solubility: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in medicinal chemistry screening, where optimal solubility supports efficient bioassay development. Reactivity: 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% is used in ligand design for coordination chemistry, where enhanced reactivity enables rapid complex formation. |
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In a world where specialty heterocycles shape pivotal reactions in pharmaceuticals, materials research, and fine chemicals, 6-(Hydroxymethyl)imidazo[1,2-a]pyridine catches the eye. Here on our line, we spend long hours making sure every batch achieves consistent performance and reliable purity—not just for laboratory curiosity, but for real-world utility. Over the years, customers have approached us with plenty of questions about how this compound performs, its notable features, and where the real advantages lie over similar reagents. Drawing from daily experience working through synthesis, purification, and shipment, we want to break down those points in language that comes straight from the original source.
What's most remarkable about 6-(Hydroxymethyl)imidazo[1,2-a]pyridine is its versatility across chemical transformations. The 97% purity we produce stands well above tertiary arrays that often hover around low 90s. This extra degree of refinement only comes after attention to raw input quality, reaction monitoring, and hands-on crystallization. Working in process laboratories and scaling up for kilo-lots, we’ve seen first-hand that substandard grades cloud downstream reactions, leave extra side products, and trigger more waste. For medicinal chemists looking for crisp, rapid reactions in heterocycle frameworks, these impurities slow progress. The cleaner the material, the fewer headaches later.
Our typical lot bears a clear, pale solid appearance—thanks to an integrated purification route involving controlled solvent extraction and repeated washing. Time spent on the workbench inspecting lots becomes worthwhile as even a slight discoloration signals a red flag: a sign of leftover byproducts from incomplete cyclization or partial oxidation. There’s no shortcut here. Spotting these at the source means you’re less likely to see contaminant-activated polymers or sticky residues in sensitive research or pilot lines. That’s a detail we drill into with every production cycle.
Scientific literature demonstrates that 6-(Hydroxymethyl)imidazo[1,2-a]pyridine forms the backbone for research projects spanning fluorescence studies, biological activity screens, and functionalized derivatives. Our long collaboration with chemists developing kinase inhibitors and imaging probes lets us see exactly where the material gets put to the test. Only batches showing minimal water content and stable melting behavior advance from the warehouse. Finer grades translate to fewer repeated syntheses and better reproducibility in published results.
Stability checks occupy an outsized spot in our workflow. Compounds with exposed hydroxyl groups sometimes degrade under careless storage. In our factory, the product’s packaging takes account of both oxygen and ambient moisture: every order ships with clear indicators to detect any early onset of degradation. That’s not just extra packaging; it answers a real problem encountered in bulk chemical logistics—where months in transport can erode material quality long before it reaches the end user’s bench.
From the earliest gram-scale syntheses up through pilot plant campaigns, we’ve settled on a 97% grade that firmly separates itself from run-of-the-mill stocks. Each batch earns documentation of nuclear magnetic resonance spectra and chromatographic purity. We resist the temptation to cut corners at this stage, because stricter internal specifications build up trust over years rather than weeks. CAS Number: 912773-23-0 serves as the unique identifier, but what truly differentiates our runs is the consistently high HPLC purity. This avoids ambiguous minor isomers that sneak through in quick, low-spec operations.
Moisture sensitivity means every production shift ends with solid material swiftly containerized under controlled atmosphere. A slight delay, especially in a humid region, lets micrograms of water creep in—enough to tip a reaction in another lab out of range. We keep loss on drying well below accepted analytical thresholds, double-checking each sample’s mass before sealing drums and glass bottles. For research groups and process developers alike, this gives confidence that the data logged one month matches observations the next.
At face value, many imidazo[1,2-a]pyridines look almost interchangeable. The devil sits in the details. Adding a hydroxymethyl group at the 6-position unlocks attachment points for custom ligand design and cross-coupling strategies. We’ve seen emerging therapeutic targets demand these modifications for selectivity or tuning solubility profiles. In contrast, the 2- or 3-hydroxymethyl analogues miss the mark for these niche approaches. Some users attempt to make do with lower-substituted variants, only to double back as yields and selectivity lag behind.
Imidazo[1,2-a]pyridine on its own sees frequent deployment as a reference scaffold in combinatorial synthesis. Drop in the 6-hydroxymethyl group, and now you’re wiring new functionalities using straightforward activation—opening a bigger field for derivatization. In our discussions with academic and industrial collaborators, getting access to a clean, ready-to-use form of the 6-HMPy variant shaves six weeks or more from custom runs. Start with the right base material, and efficiency scales. Chemical manufacturers understand these delays carry costs no lab wants to bear.
Colleagues in fine chemical synthesis sometimes ask why we invest so much manpower in Q&A checklists on each lot. From our perspective, chasing higher standards reduces support calls and material returns. Over the years, chemists told us that their past experiences with off-spec merchandise forced them to troubleshoot not just the obvious—like melting point or color difference—but reaction times, product purities, and even isolation yields. At our plant, we log every deviation, analyze failed crystallizations, and run lab-scale retrosynthesis to trace impurities back to their source.
In the early batches, if pH drifted at quenching, residual base would escape through to the final material. Even a fraction of a percent could bake in oxidative tints, clouding end-user results. We leaned on decades of collective plant experience, walking through small changes: altered quench speeds, tightened cooling curves, and sharper phase separation logs. The improvements remain visible not as bullet points in a catalog, but in the reduction of customer complaints and requests for replacement shipments.
Some compounds lose value not from their chemistry, but from how they’re stored and shipped. We encountered that early, moving multiple kilogram lots internationally. Moisture ingress, rough transport, and temperature swings exposed the weaknesses in run-of-the-mill packaging. Examples like 6-(Hydroxymethyl)imidazo[1,2-a]pyridine show why a generic polyjar might not cut it—especially for long-haul air freight or non-climate-controlled sea freight. Materials improperly sealed absorb atmospheric water or slowly decompose, showing up in yellowing or reduced sharpness in NMR spectra.
Our warehouse teams work closely with packaging engineers, building solutions like laminated foil liners or inert atmosphere pouches for high-sensitivity orders. Each step—right down to labeling with full traceability—comes from real-world incidents where a slip meant a whole shipment turned into waste. Working alongside our shipping partners, we’ve cut down on these risks by building redundancy into the system. Return rates dropped, and recurring clients voice greater trust.
Real chemical advancement demands reagents that won’t let users down mid-synthesis. In the lab, 6-(Hydroxymethyl)imidazo[1,2-a]pyridine serves as a stepping stone for advanced heterocycle assembly, including Suzuki-Miyaura cross-couplings, nucleophilic substitution, and cyclization schemes. Our partners in drug discovery and agrochemical development push its use toward fragmentation studies, rapid-access analogs, and screening against pathogenic bacteria. In diagnostics, researchers value its reliable response in fluorescence-based binding assays, where even a trace contaminant can throw off detection thresholds.
The sequence stays simple: consistent reagent means consistent performance across campaigns. We’ve seen firsthand how researchers with tight project timelines rely on this predictability. They can avoid extra rounds of chromatography or laborious purification steps. Instead, experiments can launch based on literature protocols, saving time and effort.
Most product innovation doesn’t happen in isolation. We depend on a feedback loop straight from researchers, pilot plant engineers, and formulators. Early users flagged problems back when we released our first few lots: residual traces, small deviations in crystallinity, or difficulty dissolving. Our technical group responded by setting tighter lot-release standards, assigning full analytical validation as an integrated part of the QC process, not just paperwork. Adjustments took effort but earned better long-term results, especially when users reached out with new experimental needs or sought bulk customizations.
Some customers once attempted to work with less pure alternatives to cut costs. Usually they circled back citing new side-products, lower yields, or amplified effort in routine extractions. In direct dialogue, we showed precisely where higher upfront investment paid off: fewer project delays, less troubleshooting, and cost savings over the span of the whole project rather than a single invoice. That’s the real economy—understanding total workflow and operational downtime.
Chemical manufacturing today demands not just high-purity outputs but responsible stewardship. Within our plant, closed-loop solvent recovery and minimized emission standards do not just meet regulations, but reduce workplace exposure and improve batch reproducibility. Handling 6-(Hydroxymethyl)imidazo[1,2-a]pyridine fits that model. We reuse and distill solvents where possible. Waste streams undergo on-site treatment before disposal, shrinking our environmental footprint. Lab teams constantly refine protocols to cut unnecessary steps, all in the service of safer and greener chemistry.
Our experience teaches that sustainability isn’t a line-item—it’s the sum of hundreds of local choices: energy-efficient process lines, optimized filtration equipment, and figuring out how to get the most out of every raw input. The rewards materialize not just in paperwork, but in worker safety and product stability. Partners visiting the plant see this firsthand: clean workspaces, streamlined loading bays, and materials that do not sit unsupervised before shipment.
New research and commercial demand for heterocyclic building blocks keep shifting. A decade ago, 6-(Hydroxymethyl)imidazo[1,2-a]pyridine sat on the fringes of specialty products, requested only by a handful of process development labs. With new kinase targets, imaging sciences, and modular therapeutics, the same material now sees wider adoption. Researchers pressing toward faster discovery cycles look for starting materials that save them both time and technical troubleshooting. A high-purity, reproducible compound like ours meets that benchmark.
We watch annual orders, track market queries, and adapt manufacturing targets not through speculation, but by working through detailed inquiries. Some clients share early demand estimates—a sign of their trust in our future supply. Rather than chase every new trend, we focus on proven improvements: solid analytical data, documented supply chains, and readiness to customize bulk orders. That readiness doesn’t appear overnight, it’s forged by repeated collaboration and problem-solving.
All the purity in the world means nothing if the compound sits stuck in customs or degrades en route. Working at the source, we see the benefit of direct communication with logistics teams and customs advisors. Each lot carries clear paperwork, which matches the real material shipped, no substitutes. We notice customers often prefer direct procurement from manufacturers like us, bypassing resellers who might store versatile materials under uncertain conditions or blend lots to cut costs. Receiving precise, unblended batches reassures project managers and synthetic chemists alike.
Supply chain interruptions put a strain on research timelines. Holiday seasons, port congestion, and trade disruptions taught us to adapt by increasing onsite finished-goods inventory and by diversifying our preferred transport carriers. Planning for uncertainty isn’t glamorous, but serves as the backbone for uninterrupted lab work.
| Characteristic | Manufacturer's Approach |
|---|---|
| Purity Level | 97% by HPLC, validated for each lot |
| Batch Size | Customizable, scalable from gram to kilogram |
| Storage Handling | Low-moisture, light-protected, sealed glass or foil pouches |
| Key Application | Medicinal chemistry, fine chemicals, fluorescence studies |
| Difference vs. Other Grades | Less carryover, no batch blending, stricter impurity controls |
Manufacturers learn quickly that each product tells a story, one written in yield curves, impurity logs, and repeated outcomes on benches far from our own. 6-(Hydroxymethyl)imidazo[1,2-a]pyridine 97% may look simple to outsiders, but after overseeing production runs and tallying up direct feedback, the value sits in certainty. Certainty that each container matches what’s on the label. Certainty that reagents integrate smoothly into even the most demanding applications. Certainty that our attention to environmental, process, and analytical standards translates into fewer surprises.
From our perspective, delivering this compound isn’t just about producing another batch, but shaping a longer partnership with every order we fill. Years of honing the process and listening to users makes the difference between a standard reagent and a trusted tool in research. That’s where expertise earned over decades pays for itself, and where confidence comes not from generic advertisements, but from hands in the mix—right where chemistry reaches its fullest potential.
