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HS Code |
669856 |
| Product Name | 4-Bromo-6-Nitro-Indazole |
| Molecular Formula | C7H4BrN3O2 |
| Molecular Weight | 242.03 g/mol |
| Cas Number | 1435930-94-7 |
| Appearance | Yellow solid |
| Melting Point | 193-197°C |
| Solubility | Slightly soluble in DMSO and DMF |
| Purity | Typically ≥ 97% |
| Storage Temperature | 2-8°C |
| Smiles | Brc1ccc2[nH]nc([N+](=O)[O-])c2c1 |
| Inchi | InChI=1S/C7H4BrN3O2/c8-4-1-2-5-6(3-4)9-11-7(10(12)13)5/h1-3H,(H,9,11) |
As an accredited 4-Bromo-6-Nitro-Indazole factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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Modern labs keep discovering new pathways, looking for the next useful molecule. 4-Bromo-6-Nitro-Indazole stands out as one of those important compounds that often sits quietly behind the scenes, shaping breakthroughs in chemical research and industry. With the chemical formula C7H4BrN3O2, this substance brings both versatility and unique attributes to the table—qualities that have made it a regular fixture in advanced synthesis projects, from pharmaceuticals to fine chemicals. For researchers who care about purity, efficiency, and progress, having reliable access to this compound means the difference between a stalled project and a new innovation on the bench.
The indazole backbone doesn’t show up by accident in chemistry labs. People work with it for its stability and ability to host different groups through substitution, giving a jumpstart to a series of potential applications in science and technology. In this molecule, the bromine atom occupies the 4-position on the indazole ring, and a nitro group is attached at position 6. These modifications change its electronic character, directly impacting how it reacts. For chemists chasing novel pathways—whether that’s building a better drug molecule or designing new functionalized materials—a compound with a tailored structure like this one often plays a major part in moving their work forward.
Not all batches are created equal. With this product, researchers look for high purity—typically no less than 97% when delivered from reputable suppliers. Impurities have a way of turning a promising experiment into a complete headache, especially in synthesis projects that demand precision. Consistent appearance, usually a yellow to brownish solid, leaves little room for confusion. Melting point checks, which often sit between 195 and 210°C, offer a quick way to confirm you have the right material on hand. These aren’t just numbers in a brochure; they are the details that help scientists avoid project delays or costly re-runs.
The adaptability of 4-Bromo-6-Nitro-Indazole makes it more than a simple building block. Pharmaceutical developers often need tailored molecules that go beyond what nature provides, and the indazole system, with its modifiable positions, opens doors to create new medicinal scaffolds. By adding a bromine atom and a nitro group at specific positions, this variant gives access to new chemical reactivity, helping with coupling reactions, selective reductions, and other transformations. Anyone who has struggled with multi-step syntheses knows that shaving off even one step—thanks to well-placed reactive sites—can save weeks of effort and thousands of dollars.
Not all indazoles behave the same. Substituting the indazole core with different groups creates a broad range of properties and reactivities. 4-Bromo-6-Nitro-Indazole carries both strong electron-withdrawing groups. This means it reacts differently than plain indazole or a version with just one group, like 6-nitro-indazole or 4-bromo-indazole. Sometimes, having both groups present actually makes it easier to do cross-coupling reactions, like Suzuki or Buchwald-Hartwig, offering routes to molecules that might otherwise be out of reach. It also reduces potential side reactions that trip up less specialized compounds. One can see the value for researchers trying to keep reaction conditions mild, cut down on purification struggles, or steer clear of hazardous byproducts.
Researchers care about access and quality—no one starts a twenty-step synthesis with sketchy chemicals. Trace impurities, unexpected hydration, or unknown isomers can throw off entire projects. Reputable suppliers address these concerns by adopting advanced purification techniques, including column chromatography and recrystallization, to keep standards tight. Often, they back each lot with certificates of analysis covering details like melting point, chemical purity (tested by HPLC and NMR), and even residual solvent checks. For labs operating under Good Manufacturing Practice or similar rules, these assurances can make a difference between regulatory headaches and smooth progress.
Every researcher knows that few reactions ever go as planned. That’s why chemists look for molecules that can open multiple synthetic doors, not just one. The 4-bromo group often serves as a handy site for palladium-mediated couplings, letting scientists stitch on aromatic or heteroaromatic partners with confidence. Meanwhile, the nitro group can be selectively reduced, swapped for an amino group, or even used to guide new ring closures. In years of lab work, I’ve seen how the correct combination of functional groups can shorten projects by entire weeks, offering both flexibility and dependability in real-world workups.
In pharmaceutical circles, indazoles often show promise as kinase inhibitors, anti-inflammatory agents, or antimicrobial backbones. The pattern of substitution—where the bromine and nitro groups sit—alters how the molecule fits into enzymes or targets proteins. Chemists frequently use this bromo-nitro combination, so they can quickly explore new analogs by making small tweaks, such as swapping the bromine for a different group or flipping the nitro to an amine. This process speeds up drug discovery, since teams can quickly move from preliminary hits to optimized compounds. Access to high-quality intermediates like 4-Bromo-6-Nitro-Indazole usually means the difference between months of delay and the next big lead compound.
Chemical development used to mean small vials in academic labs, but demand for scaled-up production keeps rising. Industrial users—whether pharmaceutical manufacturers or companies making agrochemicals—risk major losses if the product quality slumps or shipments stall. Consistent batch-to-batch performance isn’t a luxury; it’s a requirement. Smart suppliers track each step, monitor impurities, and adapt storage solutions to protect the integrity of this compound. If you’ve ever been through a failed scale-up, you know that switching to a poor-quality input can throw weeks of troubleshooting onto a project, burning resources and eroding trust between lab and production teams.
International collaboration pushes chemical research forward, but no one wants customs delays or mislabeled products lurking in a shipment. Proven suppliers don’t just meet purity specs—they deliver clear labeling, standardized documentation, and straightforward transit monitoring. These habits protect labs from costly re-work. Over the years, working with materials from trusted producers has meant fewer headaches, simpler regulatory filings, and more predictable research timelines. When delays or confusion are trimmed at the sourcing stage, scientists stay focused on solving the actual problems their projects were designed to address.
Every experienced chemist can recall a project slowing to a crawl because one batch looked slightly off. Maybe it clumped from exposure to humidity, or trace solvents nudged a reaction off-course. Mitigating these issues means using tight packaging, quality control checkpoints, and—when things really matter—routine re-validation of stored stocks. A robust supplier relationship helps too, as clear communication can get problem lots replaced before a project misses a deadline. Investing in proper inventory practices, with regular checks and careful environmental controls, cuts down on these incidents. The moments you spend on quality assurance upfront save hours of grief in the long haul.
No one wants to deal with unnecessary risks, but some compounds need more attention than others. This compound, with its active nitro and bromo groups, asks for proper handling—nothing outlandish, but enough care to respect its chemical potential. Storing it in a dry, cool spot, away from direct sunlight or oxidizing agents, keeps the material stable across months or years. Wearing gloves, eye protection, and keeping proper airflow cuts the risk of skin or lung irritation, especially when dealing with any particulate compound. My own approach in the lab always involves a designated weighing station, careful cleaning of nearby surfaces, and a habit of logging every opening and closing of the storage vial. These little routines add up to a safer, more predictable workspace.
Modern chemistry isn’t just about making new compounds—it’s about understanding the life cycle of every reagent. Efficient synthesis with minimum waste reduces the environmental footprint from each project. Researchers embracing green chemistry principles might select this compound because its reactivity allows for fewer synthetic steps, minimizing the need for harsh reagents. Disposal happens by following approved protocols, never dumping leftovers down a drain or letting stocks build up unused. As labs and companies come under increasing pressure to report on waste and resource use, making smart choices at the raw material level helps meet regulatory demands and corporate sustainability goals.
Although pharmaceutical R&D forms the largest audience for this compound, its unique attributes haven’t gone unnoticed elsewhere. In agricultural labs, tailored indazoles sometimes play a role in developing new herbicides or plant-growth regulators. The pattern of reactivity enabled by bromo and nitro groups can help design safer, more effective substances. Material science researchers, always looking for novel nitrogen-rich cores or electron-deficient building blocks, have begun to investigate indazole derivatives as parts of sensors or molecular switches. In every corner of industry, the name of the game is specificity: the right starting material often unlocks possibilities that nobody saw at the outset.
Academic labs, where new ideas form and surprising results often appear, rely black-and-white on advanced reagents like 4-Bromo-6-Nitro-Indazole. By having access to high-quality samples, students and investigators up their odds of publication, patent filings, or successful partnerships. Professors and grant-writers know that reproducibility—using trusted sources and tightly controlled inputs—underpins their reputations and the reliability of published research. The broader scientific community wins too, since transparent sourcing and well-characterized chemicals help create repeatable, believable science.
Younger researchers often run up against logistical nightmares. Delayed shipments or batches that fall outside specifications sap energy and eat up valuable time. Reliable access to reagents like this one allows projects to take flight quickly. Experienced colleagues help set up clear evaluation criteria, so every new acquisition gets checked for melting point, solubility, and performance in small-scale pilot reactions. Plenty of scholars remember the sting of re-running weeks of experiments due to hidden impurities. For research groups running tight ships, these early checks become teaching moments—and habits that last throughout a career.
Getting a new compound into the reaction scheme shouldn’t introduce a mountain of paperwork or troubleshooting. Standardized lots, with clear technical documentation and full analytical data, make life on the bench run smoothly. If there’s ever uncertainty about storage, shelf life, or stability profiles, open lines to technical support teams remove guesswork. For industrial chemists balancing quarterly quotas and for grad students racing grant timelines, these support systems directly enable faster, more reliable results. The right outsourcing partners cut learning curves and keep people focused on real science, not running circles over bad lots.
Building new compounds, drugs, or materials means making hundreds of small decisions. Selecting a building block like 4-Bromo-6-Nitro-Indazole means more than ticking a box—it means weighing reactivity, purity, cost, safety, and reliability. Over the years, I’ve learned that making these choices with eyes open pays dividends. At each step, someone’s data, reputation, or funding sits on the line, and having the right chemical in hand means everything. From startups breaking into biotech, to established labs setting industry standards, the quality of inputs defines the pace of progress.
New techniques keep appearing. Automated synthesis platforms, constant flow reactors, and robotic workcells ask for dependable, well-characterized reagents. As science moves steadily forward and complexity increases, suppliers who focus on quality, not just quantity, make themselves indispensable. Chemists want to spend time thinking creatively, not scrambling to identify the source of unexpected side products. Smoothly integrating compounds like this one into high-throughput screening, scale-up campaigns, or iterative design keeps research teams operating at their best level.
Taking a broad view, the value of a compound like 4-Bromo-6-Nitro-Indazole reaches further than a simple bottle label. Each lot feeds into the cycle of discovery, optimization, and new application. Choosing dependable suppliers, checking every batch, and keeping a sharp eye on storage and documentation leads to better science, tighter timelines, and more rewarding collaborations. Over the years, I’ve watched whole research campaigns shift course because teams made the right—or wrong—choices at the starting line. Reliable access to advanced intermediates isn’t an extra; it’s the backbone of any serious scientific endeavor.
From startup biotech labs to large-scale manufacturing and everything in between, the details behind seemingly obscure compounds like 4-Bromo-6-Nitro-Indazole often separate chaotic, meandering projects from successful, published, and impactful outcomes. It shapes synthesis strategies, influences workflow, supports drug design, and links university creativity with industrial rigor. As the pace of discovery picks up, treating these foundational choices with the care they deserve will continue to drive science—and every innovation it unlocks—faster and further than ever before.
