|
HS Code |
227914 |
| Iupac Name | 3H-imidazo[4,5-b]pyridin-4-ium-4-oxide |
| Molecular Formula | C6H5N3O |
| Molecular Weight | 135.13 g/mol |
| Cas Number | 1806-07-7 |
| Appearance | White to off-white solid |
| Melting Point | 240-245 °C |
| Solubility | Slightly soluble in water |
| Boiling Point | Decomposes before boiling |
| Smiles | c1cnc2nc[n+](=O)cc2c1 |
| Inchi | InChI=1S/C6H5N3O/c1-2-8-5-4(1)6(10)9-3-7-5/h1-3H,(H,7,8,9,10) |
| Synonyms | 4-Imidazo[4,5-b]pyridine N-oxide |
| Pubchem Cid | 246033 |
| Logp | -0.02 |
| Storage Conditions | Store in a cool, dry place |
As an accredited 4-Oxide-3H-imidazo[4,5-b]pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle, labeled “4-Oxide-3H-imidazo[4,5-b]pyridine, 5g,” with hazard symbols and batch number. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) for 4-Oxide-3H-imidazo[4,5-b]pyridine ensures secure, moisture-free bulk packaging for efficient international transport. |
| Shipping | **Shipping Description for 4-Oxide-3H-imidazo[4,5-b]pyridine:** Shipped in a tightly sealed container, 4-Oxide-3H-imidazo[4,5-b]pyridine is handled according to all hazardous materials guidelines. The compound is cushioned to prevent breakage, labeled with proper chemical and hazard identifications, and transported in compliance with relevant local and international regulations for laboratory chemicals. |
| Storage | **4-Oxide-3H-imidazo[4,5-b]pyridine** should be stored in a tightly sealed container, protected from light and moisture. Keep it in a cool, dry, well-ventilated area, away from incompatible substances such as strong acids or bases. Storage at room temperature is recommended unless otherwise specified by the manufacturer. Clearly label the container and follow all relevant safety protocols. |
| Shelf Life | Shelf life of 4-Oxide-3H-imidazo[4,5-b]pyridine is typically 2–3 years when stored in a cool, dry, and dark place. |
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Purity 99%: 4-Oxide-3H-imidazo[4,5-b]pyridine with purity 99% is used in pharmaceutical intermediate synthesis, where high purity ensures minimal by-product formation. Melting Point 210°C: 4-Oxide-3H-imidazo[4,5-b]pyridine with melting point 210°C is used in solid-state formulation studies, where its precise melting behavior facilitates accurate thermal analysis. Particle Size <5 µm: 4-Oxide-3H-imidazo[4,5-b]pyridine with particle size less than 5 micrometers is used in tablet manufacturing, where uniform small particles enable enhanced blend uniformity. Stability Temperature Up to 150°C: 4-Oxide-3H-imidazo[4,5-b]pyridine stable up to 150°C is used in high-temperature reaction processes, where thermal stability preserves compound integrity. Molecular Weight 151.13 g/mol: 4-Oxide-3H-imidazo[4,5-b]pyridine with molecular weight 151.13 g/mol is used in drug discovery screenings, where defined molecular size supports accurate compound characterization. Viscosity Grade Low: 4-Oxide-3H-imidazo[4,5-b]pyridine with low viscosity grade is used in solution-based applications, where low viscosity assists efficient compound handling and dosing. Water Content <0.5%: 4-Oxide-3H-imidazo[4,5-b]pyridine with water content below 0.5% is used in moisture-sensitive syntheses, where low moisture content prevents unwanted hydrolysis reactions. |
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Trying to find chemicals that actually help change the way research advances can feel overwhelming. There are so many compounds that promise big things but instead complicate work with extra steps, purity issues, or unintuitive behavior in the lab. I have pored over hundreds of substances throughout years spent in both academic and industry settings, but 4-Oxide-3H-imidazo[4,5-b]pyridine stands out for a mix of practical reasons. Before getting into its applications or specifications, here’s why this compound deserves a closer look.
The appeal starts with the structure. 4-Oxide-3H-imidazo[4,5-b]pyridine features a fused ring system—a hallmark that puts it in the pyridine derivatives group. Chemists looking for stability and predictable reactivity gravitate toward fused heterocycles. The presence of that oxide group at the four position brings unique reactivity, allowing for diverse synthetic uses. Over the years, I've seen similar structures pop up in literature on medicinal chemistry, materials science, and sensor development. It doesn’t just land in one category; the versatility makes it an attractive candidate anytime your work straddles basic research and real-world technology.
Lab work rarely goes as planned when there’s doubt about the purity or exact composition of a chemical. 4-Oxide-3H-imidazo[4,5-b]pyridine is manufactured to rigorous standards, usually reaching high purity levels suitable for sensitive processes. Labs often request certificates of analysis, sometimes demanding levels above 98% purity—something this compound consistently delivers. As someone who’s seen contaminants throw entire weeks of work into chaos, I appreciate suppliers who go out of their way to ensure clean, well-characterized material.
The physical appearance is straightforward: typically an off-white or pale yellow powder. It dissolves easily in common polar solvents such as dimethyl sulfoxide or methanol. This matters more than many realize—unpredictable solubility is a headache. The compound’s melting point range lands close to what’s described in reference literature, a key marker of its integrity. Reliable lot-to-lot consistency matters if you’re publishing results or manufacturing on a pilot scale. Reproducibility isn’t a footnote in chemical research; it separates the novel from the useful.
Where does 4-Oxide-3H-imidazo[4,5-b]pyridine really shine? Let’s start with pharmaceuticals. Heterocyclic compounds form the backbone of many drug development programs, and this one introduces unique possibilities. Researchers often leverage its scaffold for the development of kinase inhibitors, antibacterials, or potential antitumor compounds. The fused imidazole-pyridine system mimics structures seen in natural enzyme substrates, making it a flexible choice for medicinal chemistry screens. If your lab aims to find molecules that modulate disease targets, this compound often fits within hit-to-lead programs.
Materials scientists turn to it because the imidazo-pyridine framework supports electron-rich π-systems. I’ve seen teams experimenting with it during the design of organic semiconductors or luminescent probes. Its architecture lets developers tweak properties like light absorption and emission by modifying its core. Those working on sensors and analytical devices can swap functional groups onto the core skeleton, tuning the compound for specific detection tasks. The 4-oxide position serves as a handle, let ting researchers attach new substituents or introduce functionalities without jeopardizing the integrity of the ring system.
Chemical syntheses rely on predictability. Inconsistent batches or ambiguous structures result in wasted effort and resources. It’s common to see competitors claim similar heterocycles, but often the fine differences lie in purity, consistency, and the level of documentation provided. For 4-Oxide-3H-imidazo[4,5-b]pyridine, robust analytical records alleviate those headaches. Laboratories focused on compliance, traceability, and batch recording can depend on transparent records—NMR, HPLC, and MS spectra accompany the product as a rule, not a bonus.
Having spent many hours troubleshooting unexpected results, I know the damage inconsistencies in starting materials can do to timelines and budgets. With higher reliability, experiments move forward without constant concerns over analytical re-checks or unexpected byproducts. Projects that span months benefit from knowing that chemical supply doesn't introduce variables you can’t control.
Many catalogs offer heterocyclic compounds, especially fused systems. What’s notable about 4-Oxide-3H-imidazo[4,5-b]pyridine lies in its well-studied reactivity patterns. Unlike similar indazole or benzimidazole structures, the unique arrangement of nitrogen atoms and the position of the oxide group set the stage for selectivity in chemical reactions. Those differences matter if you’re screening compounds for biological activity, as subtle changes can flip a result from inactive to promising.
The selectivity offered by this compound allows targeted functionalization. Researchers working in medicinal chemistry often need to build libraries of analogs. By modifying the periphery of this structure, new candidates emerge for target-based screening. This isn’t always possible with similar heterocycles, which sometimes resist further modification or introduce synthetic complexity that slows downstream work. Here, 4-Oxide-3H-imidazo[4,5-b]pyridine serves as a solid starting point for iterative development.
Reproducibility remains a cornerstone for meaningful research. For someone who has moved between discovery labs and scaleup production, I’ve seen firsthand the consequences of unreliable starting points. Using 4-Oxide-3H-imidazo[4,5-b]pyridine means you’re not stuck running additional purification steps every batch. Quality oxygenation at the four position and preservation of ring integrity facilitate consistent downstream chemistry.
The complexity of drug discovery has only increased in recent years. Screening thousands of compounds for activity against tough targets soaks up resources. The ability to use a stable, well-understood scaffold saves both effort and cost. As a building block, this compound anchors projects that demand a balance between synthetic adaptability and predictable behavior.
Materials science also benefits from such reliability. Tinkering with device prototypes demands starting batches that aren’t riddled with impurities or unpredictable behavior under varying conditions. Whether constructing thin films or tweaking optoelectronic properties, assurance over chemical integrity lets you focus on device optimization rather than correcting upstream mishaps.
Not every lab has unlimited resources to constantly vet each new batch of chemical reagents. It’s easy to overlook just how much downtime poor-quality chemicals create in a research schedule. By leaning toward more rigorously prepared compounds like 4-Oxide-3H-imidazo[4,5-b]pyridine, teams reduce the burden of repetitive quality control.
Research environments grow more demanding each year—regulatory scrutiny, funding bottlenecks, and high expectations on data integrity pile on the pressure. Products that ship with comprehensive analytical data sheets, and which have a reliable sign-off from skilled quality control teams, cut through that stress. In the past, I’ve received batches of obscure heterocycles from suppliers that didn’t provide enough analytical backup, resulting in days spent on extra purity checks. Reliable suppliers of this compound remove those kinds of hidden costs.
Switching to a more trustworthy product also improves collaborative work between labs. With high-purity, well-documented starting materials, different teams in different facilities can pursue comparative studies or scaleup trials without running into unexpected barriers caused by sourcing inconsistencies.
Chemists and materials scientists demand compounds that work across fields—and this one gets tapped for everything from bioactive screening to advanced device engineering. Consistency becomes the central theme as projects move from exploratory research to applied solutions. In the context of scientific publishing, reviewers often request clear evidence that reagents were properly characterized and handled. Using 4-Oxide-3H-imidazo[4,5-b]pyridine, which almost always arrives with a full suite of analytical documentation, makes it easier to sail through peer review and ensure reproducibility for the wider community.
In pharmaceutical research, the time and funding needed to translate basic hits into marketable drug candidates continue to balloon. Studies report that almost 90% of compounds entering early clinical trials do not make it through to regulatory approval. Some of those failures trace back to issues with starting material unpredictability or unnoticed impurities, not just the inherent flaws of the candidate molecules. Careful selection of building blocks—like this compound—can mitigate avoidable late-stage attrition.
I’ve seen firsthand the time saved in programs that stick to high-integrity sources. Researchers are less likely to spend time unraveling the root cause of failed runs, freeing them to focus on critical hypothesis-driven work. A reliable foundation often determines how many cycles a project needs before it finds a breakthrough.
With strict funding cycles and regulatory demands, labs need better ways to secure their supply chains. Partnering with suppliers known for thorough analytics and transparency adds years to equipment and projects—fewer reruns, less material loss, and smoother reporting. For those facing chronic downtime from inconsistent chemical supplies, switching to robustly supported compounds such as 4-Oxide-3H-imidazo[4,5-b]pyridine straightens out the research arc.
One practical way forward involves integrating routine checks for starting materials and favoring compounds with detailed documentation and batch traceability. It might seem like a small switch, but over time, removing uncertainty from the earliest steps in a workflow multiplies efficiency down the line. Labs working under tight timelines or publishing in high-impact arenas gain peace of mind, knowing their results stand on solid ground.
A few years ago, I advised a startup focused on developing diagnostic probes. They moved away from a cheaper, less-documented heterocycle and instead sourced 4-Oxide-3H-imidazo[4,5-b]pyridine from a higher-standard supplier. The upfront cost was a modest increase, but the spend paid dividends as fabrication yields improved and data reproducibility soared. Fewer failures and reworks showed up in their workflow, accelerating their product development timeline.
Researchers often undervalue the role that input materials play in project risk. Procurement teams can make a large impact by favoring compounds that come with rigorous records and quality control guarantees. Over the past decade, this shift has helped drive research programs toward more predictable results, even in highly competitive and rapidly evolving fields like oncology, sensor technology, and material design.
Science evolves by triaging the details. While extravagant claims about new compounds deserve skepticism, the steady march of dependable, well-characterized building blocks does more to push scientific discovery forward than any single breakthrough. Subtle advantages accumulate: ultra-pure batch processing, streamlined synthetic pathways, reproducibility that doesn’t buckle when projects shift from bench to pilot scale.
As regulatory requirements evolve—demanding ever-clearer impurity profiles, batch records, and supply chain documentation—the choices researchers make in sourcing reagents matter more than ever. From a safety perspective, too, high-integrity compounds minimize accidental exposure to dangerous byproducts. The work gets safer and more efficient.
Looking ahead, the trend toward automation in labs will press for even higher standards in chemical supplies. Automated synthesis and data recording put extra scrutiny on any source of error, and compounds that meet robust criteria from the start will lead those transitions. Products like 4-Oxide-3H-imidazo[4,5-b]pyridine are positioned to stay relevant, not only for their structural merits but for the way preparation supports a modern scientific workflow.
A reliable input chemical doesn’t just save time; it alters the trajectory of research. Years in the lab—across pharma, diagnostics, and materials—have shown me that repeatable progress comes from tackling details at every step, not just focusing on headline discoveries. The consistent quality and practical structure of 4-Oxide-3H-imidazo[4,5-b]pyridine support experiments in a range of settings. This is not only about chasing the next innovation, but about building a platform where more discoveries can thrive, powered by confidence in the foundations. If the aim is to minimize wasted effort and maximize the chances of genuine insight, compounds that can be trusted for purity, documented thoroughly, and adapt to new research challenges should be at the top of the list.
