|
HS Code |
747682 |
| Chemical Name | 5-Fluorobenzimidazolone |
| Molecular Formula | C7H5FN2O |
| Molecular Weight | 152.13 g/mol |
| Cas Number | 183922-10-9 |
| Appearance | White to off-white crystalline powder |
| Melting Point | 218-220°C |
| Solubility | Soluble in DMSO, slightly soluble in water |
| Purity | Typically ≥98% |
| Storage Conditions | Store at room temperature, away from light and moisture |
| Smiles | C1=CC2=C(C(=C1)F)NC(=O)N2 |
| Inchi | InChI=1S/C7H5FN2O/c8-4-1-2-5-6(3-4)10-7(11)9-5/h1-3H,(H2,9,10,11) |
As an accredited 5-FLUOROBENZIMIDAZOLONE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25-gram amber glass bottle labeled “5-FLUOROBENZIMIDAZOLONE,” featuring a secure screw cap and appropriate hazard and handling information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 5-Fluorobenzimidazolone is packed securely in fiber drums or bags, totaling 7–8 metric tons per container. |
| Shipping | 5-Fluorobenzimidazolone is shipped as a solid chemical, packaged securely in air-tight, chemically resistant containers to prevent contamination and moisture exposure. Transport follows standard regulations for laboratory chemicals, requiring proper labeling and documentation. Ensure handling by trained personnel and compliance with local, national, and international shipping guidelines for hazardous substances. |
| Storage | 5-Fluorobenzimidazolone should be stored in a tightly sealed container, protected from light, moisture, and incompatible substances. Keep it in a cool, dry, and well-ventilated area, ideally at room temperature. Ensure proper labeling and restrict access to authorized personnel. Follow all safety regulations regarding chemical storage and consult the material safety data sheet (MSDS) for additional handling and storage information. |
| Shelf Life | 5-Fluorobenzimidazolone should be stored in a cool, dry place; shelf life is typically two years under proper conditions. |
Competitive 5-FLUOROBENZIMIDAZOLONE prices that fit your budget—flexible terms and customized quotes for every order.
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5-Fluorobenzimidazolone has become an integral part of our regular production cycles, reflecting both how research advances and how customers continually look for higher standards. Every batch starts with a clear objective: exceptional purity and consistent results, because in the laboratory, small deviations can ripple out into lost material, wasted time, and entire projects delayed. Over the years, new applications for 5-Fluorobenzimidazolone keep emerging from pharmaceutical development and agricultural research. For our team, the satisfaction lies in tracing the product’s journey from its earliest chemical assembly to its final impact in the world’s innovation pipelines.
Our production line handles various grades, but customer feedback guides us to focus on the model where the purity exceeds 98%. Most requests come from synthetic applications where trace impurities cannot regularly be tolerated. A single percentage point here changes the game for complex synthesis—the fluoro group introduces subtle changes in chemical reactivity, and lingering side products can sabotage downstream reactions. Here, specification sheets tell only half the story. In the heat of manufacturing, we measure quality by the batch’s performance in end-use, confirmed by internal and independent laboratory results. Our process design incorporates high-shear mixing and multi-stage purification steps to ensure consistency; operators check GC and HPLC readouts not as a tick-box exercise but as a window into the run’s true reliability.
Looking closely at benzimidazolone derivatives, chemists know that introducing fluorine at the 5-position shifts the product’s chemical landscape significantly. This particular substitution often boosts metabolic stability or alters biological activity for pharmaceutical intermediates. The fluorine atom’s effect on electron distribution, and the way it resists metabolic degradation, draws specialty pharma customers who are searching to optimize candidate molecules. We field repeated inquiries from R&D teams working to fine-tune receptor bindings, profile new antifungal agents, or model new enzyme inhibitors. The core difference from standard benzimidazolone sits right there in that subtle atom swap, which translates into fresh opportunities in chemical biology and crop science as well.
Scaling a fluorinated heterocycle to commercial quantities involves more than just scaling up a lab recipe. Benchtop chemistry rarely exposes you to the quirks of moisture sensitivity across a large reactor, or the spontaneous pressure jumps triggered by an unexpected exotherm. From material sourcing through packaging, our team relies on strict process controls and a hard-won sense for when things "feel right"—the odor of intermediates, the sound of condensers working, even the "look" of a reaction flask before the analytical results appear. Each step in our facility has been mapped, documented, and challenged by both customer audits and internal “what-if” reviews. Risk management here isn’t a line on a policy—it’s a series of lived experiences from avoiding side-product traps to expanding batch records to document every process improvement.
Every synthesis run intended for pharmaceutical R&D asks for a new kind of diligence. Molecules based on 5-Fluorobenzimidazolone have carved out their place as essential tools for those seeking improved ADME properties or looking to escape metabolic breakdown common with unmodified benzimidazolones. We’ve seen the product head toward kinase inhibitor scaffolds, exploratory anti-infectives, and even niche CNS candidates. It takes thoughtful inventory management, meticulous packaging, and reliable logistics to avoid extended delays for these demanding timelines. Our production runs often coordinate closely with client chemists to align on routing, scheduling, and contingency stock—as delays upstream can stall whole research pipelines.
A significant portion of our shipments cross over into agricultural research, feeding into discovery projects focused on new fungicides and plant-protection agents. The fluorine atom’s effect can tip a molecule from "inactive" to "field ready" by ramping up environmental stability or fine-tuning selective toxicity. Our customers regularly bring us requests for tailored lots, and as a manufacturer, we place clear boundaries between materials intended for research and those destined for further scale-up or regulatory submission. Our in-house documentation allows partners to trace supply history and verify compliance with any investigational project requirements. Here, trust comes as much from disciplined shipping logs and secure sample vials as from molecular quality.
Long-term product stability depends on tightly managed storage conditions and careful material handling at every transfer step. Even trace moisture or packaging that lets in air seeps into results. We learned early on how important it is to pair robust environmental controls (low humidity, narrow temperature bands) with clear batch labeling and first-in, first-out stock tracking. Every drum or bottle receives a barcode scan and is reconciled with digital records immediately. This habit minimizes the risk of expired or degraded material ever leaving our doors. Strict segregation of lots prevents cross-contamination; our team regularly runs refresher trainings to keep attention sharp and minimize slipups on the floor.
Most improvements trace back to open dialogue with clients or to troubleshooting on our own line. On one occasion, a batch experienced faint yellowing and barely slipped off-spec. Digging into the root cause, our operators related a subtle shift in reactor heat-up profile. Prompt process review closed the gap, and output bounced right back. This hands-on feedback loop governs every tweak we make, whether it’s a supplier update, new drying step, or recalibration of analytical equipment. Sometimes a problem flagged by a customer, such as a purity drop or trace impurity showing up downstream, becomes the origin of our next major procedure update. It’s these stories, not just data points, that push our QC forward.
The molecular modifications matter far beyond the textbook. Adding a fluorine at the 5-position on the benzimidazolone core doesn’t just “decorate” the structure; it unlocks alternative metabolic pathways and tends to increase resistance to hydrolysis. Standard benzimidazolones lack this resilience, so pharmaceutical companies often face rapid degradation in metabolic screens. The switch can also shift melting point, solubility, and downstream reactivity, impacting not just formulation development but also analytical method selection. Our own hands-on experience confirms these traits; we build them into our in-house application notes and share best practices with clients exploring new synthetic routes.
Pricing sometimes becomes a sticking point in early-stage dialogue, given the greater raw material complexity and more exacting purification steps that come with fluorinated derivatives. The added investment covers not just those upstream differences but also the extra labor to keep cross-contamination at bay—a point that doesn’t appear on the specification but shows up in customer satisfaction and project success. From a technical viewpoint, the risks of mislabeling or misdelivery climb substantially when running similar-sounding derivatives in the same facility; we offset this with color-coded labels and tightly separated workflow areas.
With specialty chemicals like 5-Fluorobenzimidazolone, production methods leave a distinct environmental footprint. We take waste management seriously, working to minimize solvent use and practicing closed-loop recycling where practical. Fluorinated waste demands heightened vigilance; each drum of spent material receives full documentation and is routed through approved channels, with oversight stretching from plant to disposal partner. Water and air emissions are constantly watched, with process improvements introduced to chip away at the environmental cost. We stockpile lessons learned, often updating internal SOPs as regulatory guidance evolves. Sustainability efforts here are not just “greenwashing” but rooted in the push to lower our facility’s impact—choosing greener synthesis pathways and investing in energy-efficient reactions where science supports the switch.
Having fresh analytical results for every lot builds credibility. Our laboratory teams run GC, HPLC, and NMR checks for each product release, logging outcomes immediately in electronic records. Failures trigger immediate review, not later investigation. Chemical identity, purity, and appearance (often an overlooked cue) all receive direct sign-off by staff chemists. Spot checks of reference materials, supplied from trusted partners, benchmark our standards. Recurring quality variances drive “root cause” investigations that often tie back to supplier changes, altered environmental conditions, or inadvertent process drift. Experience has proven that staying ahead of these issues slashes lost inventory and builds confidence with returning customers.
Every season presents new hurdles, whether it’s delays in key fluorinating agents, interrupted logistics, or regulatory shifts in allowed imports. By keeping material procurement in-house (wherever possible), our team learns to spot early warning signs and act before supply tightens. Working closely with logistics partners, we’ve fine-tuned shipment tracking with real-time digital alerts, minimizing the risk of temperature excursions or unexpected customs holds. Sudden spikes in demand—often fueled by an R&D breakthrough or regulatory fast-track—bring challenges in load balancing, but decades in specialty manufacturing taught us to build in redundant capacity and to maintain a healthy reserve of standard reagents.
Fluorinated organics present a known challenge: handling them safely means paying attention to staff training and fostering a zero-incident culture. Our operators and QC chemists attend annual training refreshers covering hazard recognition, PPE requirements, spill response, and emergency communication. We invest in local ventilation control, reinforced containment, and regular medical checks for high-risk line workers. The spirit in our shop is one of collective care, where experienced colleagues mentor new arrivals and safety is everyone’s concern, not just a supervisor’s checklist. Regular incident reviews, even for minor anomalies, keep lessons circulating fast and foster a sense of shared purpose.
Taking 5-Fluorobenzimidazolone beyond the status quo means owning each phase, from raw material auditing to end-user troubleshooting. As a manufacturer, we dig deeper into every client interaction, seeing it as a chance to refine our process, regardless of batch size or technical challenge. Our internal technical bulletins reflect real lessons—case studies from production hiccups, solutions co-developed with researchers, and procedural tweaks born out of late-night troubleshooting. These experiences don’t stay locked away; they color the way we coach our operators and inform every future process modification.
Greater attention to traceability means all data flows upwards—from line logs to senior chemists—without bottlenecks or jargon. This constant open-loop feedback has shortened the correction time from weeks to days, letting us get better with every production round. By maintaining direct oversight over each chemical transformation, every purification pass, and every final shipment, we produce material that customers repeatedly trust and recommend for high-stakes R&D.
Every few years brings fresh regulatory updates, tightening purity demands or revising handling protocols for fluorinated compounds. Our compliance group stays ahead by preemptively auditing both facility procedures and packaging methods, seeking even the smallest gaps. Where standards evolve, we adjust quickly, retraining staff and updating digital documentation, so nothing slips through the cracks. Clients often call out our ability to shift with these demands—minimizing disruptions while safeguarding the results of their downstream chemistry.
Where possible, we solicit direct feedback from long-term customers to shape next-generation offerings: finer-control small lots, expanded documentation, or retooled syntheses to lower environmental impact. Our laboratory teams experiment regularly, running parallel microbatches to test alternative solvents, shorter cycle times, or new purification aids. Shared learning travels quickly here, especially where production successes overlap with customer-led discoveries. As demand shifts—or as regulatory priorities realign—we treat every change as a prompt for closer collaboration, not just an operational puzzle.
Stories sustain us more than statistics. One researcher alerted us to an impurity trend that had eluded internal detection but became obvious after a scale-up in their facility. That conversation spurred a process overhaul, added a chromatographic checkpoint, and built a closer relationship. Another client found their screening experiment derailed by slow shipments during a logistics crunch. Working together, we redesigned our inventory management for faster emergency response—a shift that’s now baked into every urgent delivery, benefitting all downstream clients.
Each cycle through the plant closes another loop—not just for process statistics or environmental reports, but for the invisible network of researchers, developers, and innovators who rely on specialty compounds to shape tomorrow’s discoveries. From the shop floor to the R&D bench, producing 5-Fluorobenzimidazolone remains a lived experiment in learning, collaborating, and improving, batch after batch.
