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HS Code |
215983 |
| Compound Name | propan-2-one compound with imidazo[1,2-a]pyridine (1:1) |
| Other Names | acetone-imidazo[1,2-a]pyridine complex |
| Molecular Formula | C6H6N2·C3H6O |
| Molecular Weight | 188.23 g/mol |
| Appearance | crystalline solid |
| Solubility | soluble in common organic solvents |
| Cas Number | 146443-09-6 |
| Chemical Class | heterocyclic compound complex |
| Storage Conditions | store in a cool, dry place, tightly closed |
| Stability | stable under recommended storage conditions |
| Usage | research and chemical synthesis applications |
| Hazards | handle with care, avoid inhalation and contact with skin |
| Smiles | CC(=O)N1C=NC2=CC=CC=C12 |
As an accredited propan-2-one compound with imidazo[1,2-a]pyridine (1:1) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250 g supplied in a sealed amber glass bottle with tamper-evident cap, labeled with chemical name, hazard symbols, and batch details. |
| Container Loading (20′ FCL) | A 20′ FCL contains securely packed drums of propan-2-one compound with imidazo[1,2-a]pyridine (1:1), moisture-protected. |
| Shipping | The shipping of propan-2-one compound with imidazo[1,2-a]pyridine (1:1) requires secure, airtight containers, proper labeling, and compliance with hazardous material regulations. It should be transported under controlled temperature conditions, away from direct sunlight and sources of ignition, with safety documentation and handling procedures included during transit. |
| Storage | Store propan-2-one compound with imidazo[1,2-a]pyridine (1:1) in a tightly sealed container, away from moisture and direct sunlight, in a cool, dry, and well-ventilated area. Keep away from sources of ignition, oxidizing agents, and incompatible substances. Ensure proper labeling and avoid exposure to air for prolonged periods. Follow appropriate safety regulations for chemical storage. |
| Shelf Life | Shelf life: Typically 2–3 years when stored in a cool, dry place, tightly sealed, away from light and moisture. |
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Purity 99%: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with purity 99% is used in pharmaceutical synthesis, where it ensures high-yield and minimal impurity incorporation. Melting Point 128°C: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with a melting point of 128°C is used in solid dosage formulation, where it offers thermal stability during processing. Molecular Weight 188.23 g/mol: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with molecular weight 188.23 g/mol is used in analytical standards preparation, where precise mass enables accurate quantification. Particle Size <10 µm: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with particle size below 10 micrometers is used in advanced material composites, where fine dispersion enhances mechanical integration. Solubility in DMSO >50 mg/mL: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with solubility in DMSO greater than 50 mg/mL is used in drug screening assays, where high solubility promotes consistent bioavailability profiles. Stability at 45°C: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with stability at 45°C is used in accelerated stability studies, where it maintains structural integrity over extended periods. UV Absorbance λmax 310 nm: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with UV absorbance maximum at 310 nm is used in spectrophotometric quantification, where specific detection enables reliable analysis. Viscosity Low: Propan-2-one compound with imidazo[1,2-a]pyridine (1:1) with low viscosity is used in ink formulation, where easy flow characteristics optimize printing precision. |
Competitive propan-2-one compound with imidazo[1,2-a]pyridine (1:1) prices that fit your budget—flexible terms and customized quotes for every order.
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A long career blending traditional chemistry with modern demand has shown us how critical it is to get new compounds right from the earliest stages. Propan-2-one compound with imidazo[1,2-a]pyridine, in its fixed 1:1 composition, rose from requests that kept coming in from high-level R&D labs and production engineers facing barriers with conventional reagents. The initial pilot batches already demonstrated advantages in manipulation and downstream utility. That success didn’t materialize by accident; it reflects a deep familiarity with imidazo[1,2-a]pyridine reactivity, the volatility of acetone, and how solvent-ligand partnerships shift product reliability in chemical manufacturing environments.
Propan-2-one (acetone) itself is well-understood in both academic and industrial circles, with a long legacy as a solvent, intermediate, cleaning agent, and process facilitator. Imidazo[1,2-a]pyridine, exceeding most simple heterocycles in versatility, sees use in synthesis, pharma R&D, and structural chemistry. That combination in an established stoichiometric partnership doesn’t just address mixing pains but reveals new reactivity. Careful control over molar ratios translates to a robust product that gives repeatable outcomes on both bench-top and plant-scale applications. Customers working in pharmaceutical synthesis, organic intermediates, and high-value fine chemical production regularly seek this specific pairing because freelancing molar ratios introduces unpredictability into their workflows.
Our current offering occupies a vital spot in the specialty chemicals market. Each batch of the compound is produced under monitored temperature and atmospheric controls. Consistency matters most—labs and production facilities watch for pH, solubility, and purity. We designed our system to hold water content under tight restrictions to avoid unwanted hydrolysis. High-resolution mass spec and NMR readings from random samples keep impurities at or below our promised thresholds. Storage conditions favor stability, though special packaging prevents cross-contamination from atmospheric water or external organic vapors. We never cut corners on glassware or pump seals, since even tiny leaks risk batch variability that researchers justifiably dislike.
Most questions come from folks who already use acetone or imidazo[1,2-a]pyridine in isolation but run into solubility or reaction inconsistency when scaling up or fine-tuning. This compound simplifies workflows in laboratories working on nucleophilic substitutions, cyclization steps, and condensation reactions. Direct application as a reagent or an intermediate proves especially valuable in routes requiring clean stepwise assembly of nitrogens and ring systems. That sharpens crystallinity and yield as compared to ad hoc solvent mixes or sequential addition of the raw reactants. Many process engineers report that this reduces purification time, leading to clean single-phase reactions and sharper separations during downstream chromatography. We regularly invite customer feedback and tweak our purification accordingly, since each synthesis route teaches us something new about batch-to-batch interaction.
It’s tempting for traders or distributors to overlook the fine points in process flow, but being in the manufacturing chair means these details are the entire backbone of value. We insist on traceable sourcing for raw imidazo[1,2-a]pyridine, since impurities from inconsistent vendors usually give headaches at the final synthesis step. Monitoring incoming acetone for residual organics keeps the reaction window broad, avoiding past problems with volatile impurity carry-through. The chemistry of creating a homogeneous physical compound at the 1:1 ratio, in our work, needs not just theoretical design but real equipment—precise flow rates, temperature ramps, and atmospheric corrections make or break the product’s downstream function.
Because we do this in-house, minor process modifications happen quickly. For example, as one client moved from university-scale pilot tests to an industrial reactor, our team worked side-by-side to revalidate cooling rates and agitation patterns. Such collaboration only works because we directly manage our reactors and aren’t guessing at third-party results or contract data.
Many chemists experiment with mixing acetone and imidazo[1,2-a]pyridine directly on the lab bench. That solution may serve in rapid, low-stakes assays but consistently fails in precise, multi-step workflows where even minor phase changes or incomplete dissolution introduce lost yield and unpredictable outcomes. Preparing the compound in our dedicated equipment with a controlled 1:1 ratio forms a more uniform complex, which both stabilizes key intermediates and simplifies transfer between steps. Beyond technical performance, this approach cuts down on time lost to reaction monitoring and unplanned troubleshooting.
Engineers in specialty pharma and diagnostics have reported that switching to the prepared compound cut the need for lengthy solvent prep and saved resources on purification columns. A team working on novel heterocycle drugs found their test batch conversion rates climbed more than ten percent after changing to this product from a typical in-lab solvent mix. Another researcher, focused on fluorescent probe development, achieved sharper spectral resolution and easier analytic confirmation, which supported regulatory reporting requirements.
We field plenty of questions asking how this formulation compares to simple acetone derivatives or blends using other nitrogen heterocycles. Straight acetone, regardless of its solvent grades, lacks the functional nitrogen bridge that imidazo[1,2-a]pyridine brings, and no amount of careful blending generates the same stepwise reactivity. Some labs test cheaper imidazole-acetone combinations but find they either lack stability or introduce background noise into reactions that drive separation costs up. Imidazole and pyridine, used individually, generate predictable but limited reactivity patterns. The fusion offered by imidazo[1,2-a]pyridine—and stabilized by its defined relationship with acetone—introduces both electron-rich and aromatic properties that alternative systems cannot reliably match across scales.
Cost comparisons focus narrowly, but we point to the savings on labor and time that accumulate through reduced purification steps, higher selectivity, and improved downstream workflow. We invite credentialed chemists to examine our COA data for heavy metal content, water residuals, and GC purity to confirm these statements since we build transparency into our process from raw material testing to end-of-line sampling.
Product consistency grows from years of systematic improvement. We spent time retooling distilling heads and updating detectors in response to batch variability in earlier runs. Regular calibration of temperature and humidity controls caught several otherwise invisible sources of drift. Lab workers don’t have patience for unexplained product differences, and neither do scale-up teams—it’s our job as manufacturers to do that extra testing, so no one else has to rework their protocols part-way through a critical synthesis. Our in-house team takes pride in tracking even small sensor value changes and recording every reaction iteration, giving long-term customers the confidence that each container they open will serve the same way as the last.
Packaging matters deeply for compounds with volatile properties, and our work with propan-2-one compound with imidazo[1,2-a]pyridine demonstrates this. Standard plastic drums and liners leach contaminants or allow vapor ingress, which shortens shelf-life and spoils the reproducible results our clients depend on. In response, we shifted to custom glass ampules and chemically stabilized liners, which eliminate the contact issues and moisture incursion common with lower-end drums. Larger industrial clients get their supply in double-sealed drums with an inert headspace to prevent both oxidation and solvent loss. This isn’t just a marketing pitch; reduced batch returns and fewer complaints bear out these packaging choices, saving both product and reputation.
Chemical manufacturing always carries the burden of responsible process management. Years ago, solvent handling protocols didn’t factor in acetone loss or VOC emissions—now every facility faces regulatory oversight and ecological scrutiny. We adapted by fitting our reactors with upgraded condensers and solvent recovery pumps. That not only cuts emissions but also protects margins in a competitive environment. Previous waste disposal methods lost significant product and increased environmental impact, but our new recycling and byproduct re-use initiatives have already improved yield and scored well in internal audits. Customers, especially in Europe and North America, want clear answers about green chemistry, and we not only provide them but often invite auditors to see systems in practice.
Transporting volatile or reactive compounds raises valid safety concerns. The dual-natured chemistry of acetone and imidazo[1,2-a]pyridine means our teams double-check seals, pressure readings, and documentation before shipping each batch. Regular drills and training keep our handling protocols above industry minimums. Nearby emergency response teams toured our facility and commented that our documentation and labeling practices set new standards for clarity. Direct communication with client EHS managers smooths the transition to new workflows, making sure that from the drum or ampule to the reaction vessel, users get predictable performance with hazard statements that match real-world risks.
Global compliance is more than paperwork. Each regional authority asks for a detailed chain-of-custody, validation of purity, and testing of all major parameters. We keep up with both REACH pre-registration and North American submissions for regulated ingredients. Routine spot-checking by external labs supports our internal COA process, strengthening trust with purchasing departments. Border inspections or customs detentions nearly disappeared since we began standardizing documentation methods to match both regulatory language and practical lab concerns.
Among the greatest surprises since we launched this compound is hearing back from academic researchers who find new cross-coupling reactions, or industrial partners prototyping improved process intensification strategies with our product at the center. We welcome inquiries for pilot partnership batches and nonstandard volumes—this agile approach comes directly from in-house control, not distant agents removed from actual production. Process chemists visiting our facility often leave with fresh ideas, facilitated not only by the compound but by how we invite collaboration in optimizing workflow setups and parallel reaction paths.
No chemical remains static in value as research and legislation move forward. As large pharmaceutical and specialty materials producers shift focus to smaller-batch, high-purity syntheses, the demand for defined complex reagents like this continues to grow. Technological advances in reactor control and analytic monitoring only open up further opportunities to enhance the product’s role, especially as inline analytics catch faults that old batch release tests would miss. We reinvest yearly in both plant upgrades and team training, because being a manufacturer in today’s climate demands both technical expertise and a willingness to adapt to new supply chain realities.
Strong demand for specialty reagents can easily unseat production planning in any chemical plant. By staying close to our customers’ usage patterns, we avoid the pitfalls of overproduction or lagging behind market needs. This means regular consultations with end users and the flexibility to ramp up or dial back output as necessary. Inventory isn’t just a warehouse issue; keeping buffer stocks and timed shipments ensures researchers and industrial users alike aren’t stranded and rushing to find substitutes that could derail crucial project milestones.
No process runs without hurdles. Sourcing ultra-pure imidazo[1,2-a]pyridine, especially as demand swells, required building out close partnerships with upstream producers and investing in pre-purchase testing. Adjusting logistics for small-lot pharmaceutical clients taught us a great deal about the real-world challenges of packing, documentation, and transport in regional compliance frameworks. Our high degree of in-house quality control does mean greater up-front costs, but repeat orders and longer client relationships demonstrate to us that reliability justifies every cent. Perhaps the greatest reward is problem-solving alongside clients, whether troubleshooting a reaction or finding ways to recycle or reprocess spent streams without loss of value.
Propan-2-one compound with imidazo[1,2-a]pyridine has evolved directly in response to genuine chemical manufacturing challenges. As a direct manufacturer, we see every day how this compound streamlines workflows, supports cleaner chemistry, and opens up new synthetic strategies for both R&D and production teams. Decades of hands-on experience, vigilant process control, and a culture of transparency back every container that leaves our facility. Our commitment to honest communication and real, lab-tested results sets us apart in an industry where real expertise counts. For organizations working at the front lines of pharmaceutical development, specialty research, or fine chemical production, choosing a compound backed by manufacturing experience isn’t a luxury—it’s a safeguard for both lab and business success.
