|
HS Code |
224282 |
| Productname | 3-Aminobenzofuran-2-Carboxamide |
| Casnumber | 885950-45-6 |
| Molecularformula | C9H8N2O2 |
| Molecularweight | 176.17 |
| Appearance | Off-white to beige solid |
| Solubility | Soluble in DMSO, slightly soluble in water |
| Purity | Typically ≥ 98% |
| Smiles | C1=COC2=C1C(=CC=N2)C(=O)N |
| Inchi | InChI=1S/C9H8N2O2/c10-8-4-2-1-3-7(8)9(11)12/h1-4H,10H2,(H2,11,12) |
| Synonyms | 3-Amino-1-benzofuran-2-carboxamide |
| Storageconditions | Store at 2-8°C, protected from light and moisture |
| Usage | For research and chemical synthesis purposes only |
As an accredited 3-Aminobenzofuran-2-Carboxamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 3-Aminobenzofuran-2-Carboxamide (5g) is provided in a sealed amber glass bottle with a tamper-evident cap and labeling. |
| Shipping | 3-Aminobenzofuran-2-Carboxamide is shipped in tightly sealed containers, protected from light and moisture. The chemical is packed according to standard hazardous materials regulations, using cushioning materials to prevent breakage. Shipping includes clear labeling and appropriate documentation to ensure safe and compliant transport. Temperature and handling requirements are observed as per safety guidelines. |
| Storage | **3-Aminobenzofuran-2-carboxamide** should be stored in a cool, dry, and well-ventilated area, away from direct sunlight and sources of ignition. Keep the container tightly closed and clearly labeled. Store separately from incompatible materials such as strong oxidizing agents and acids. Store at ambient temperature unless otherwise specified by the manufacturer, and ensure the area is equipped for safe chemical storage and handling. |
Competitive 3-Aminobenzofuran-2-Carboxamide prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615365186327 or mail to sales3@ascent-chem.com.
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Tel: +8615365186327
Email: sales3@ascent-chem.com
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In our years of direct experience manufacturing specialty chemicals, few compounds have sparked as much focused inquiry from our pharma and agrochemical partners as 3-Aminobenzofuran-2-Carboxamide. Synthesizing this compound is a careful dance between consistent quality and precise molecular integrity. Each workspace operation, every reaction vessel, and every purification stage reflects choices we've honed over batches — a lot of care, some creative troubleshooting, lessons from earlier syntheses, always putting the end user's performance needs front and center.
Researchers and process developers often look for building blocks that combine aromatic stability with amide functionality and accessible electronic tuning. For these needs, 3-Aminobenzofuran-2-Carboxamide stands out with its fused benzofuran core, the amide's potential for hydrogen bonding, and a free amine functional group in the right position. This molecule lends itself well to medicinal chemistry groups searching for new drug candidates, or to those looking for intermediates that can anchor further modifications — sulfonation, acylation, or condensation reactions run smoothly when the starting material keeps high purity and the correct isomeric form.
We’ve been running multi-step scale-ups and purifications on this compound long enough to recognize several pain points. Moisture control during key reactions often causes headaches for third-party handlers. Without rigorous dehydration, byproducts multiply, and post-synthesis clean-up becomes a nightmare. Our in-house controls use well-calibrated drying towers and gas blankets from the moment we begin charging raw materials.
Any manufacturer can follow a paper route for this compound, but fewer invest in spectral purity checks at every stage. We’ve adopted both HPLC and NMR at intermediate isolations, not only for the final assay. This habit catches small deviations before they spiral into yield loss or tough-to-purge side compounds. Over a hundred consecutive process runs, our in-house process optimization teams have driven yields upward and impurity profiles consistently downward — practical results that downstream users notice each time they work with our sample.
Rather than list off vague numbers, let’s focus on what our specifications mean when you open a container. Crystallinity isn’t just a point of pride for us — needle-like crystals pack tight for easy weighing, but don’t clump or dust, so you aren’t spending time breaking up cake or watching material float away. We’ve dialed in our drying steps so that residual solvents always fall under levels set by regulatory authorities. Our typical product satisfies HPLC purity over 99 percent and moisture content below 0.5 percent, batch after batch. Melting points check out within a narrow window, a reliable indicator for compound stability during both transit and storage.
Every time we've spoken to our synthetic chemistry customers, the same practical concerns crop up. Will the product dissolve quickly in common solvents during the initial reaction? Does it require extra filtration? Can it survive shipping through a hot summer without degradation or caking? Based on direct observations over years of sample shipments, we've adjusted protective packaging and added more robust internal QA before any outgoing delivery. No one wants an unusable product on the lab bench. Our return rates reflect choices we've made — less than half a percent over the last five years — and most of those stem from customer-side labeling mix-ups, not from actual product defects.
As a manufacturer, we regularly support process chemists exploring new heterocyclic scaffolds. 3-Aminobenzofuran-2-Carboxamide’s unique functional groups allow for integration into kinase inhibitor research or advanced-stage intermediates in API synthesis. Some customers have shared stories of using our product to generate small focused libraries — sometimes just a few milligrams at a time — and other times preparing multi-gram lots for toxicology profiling. Our technical support teams collect feedback, gauge new experimental needs, and fine-tune production batches to fit chemo-informatics pipelines used in drug discovery.
Outside pharma, research into crop protection has drawn on this intermediate's structural set-up. The electron-deficient carboxamide can take up further substituents, providing key advantage in synthesizing more elaborate agrochemical ingredients. Our customers value predictability; a reproducible starting material saves them hours, sometimes days, in costly rework.
It’s easy to talk about “species” of benzofuran carboxamides, but only someone who’s generated and handled these compounds day in and day out sees how subtle tweaks in substitution patterns impact everything from solubility to stability. For example, the amino group at the 3-position — rather than para or meta — delivers a different reactivity profile compared to related isomers. Chemists tell us that a methyl substitution in place of the amino group might save them a step, but the reactivity windows change, sometimes stalling downstream processes entirely or introducing side reactions that cost both time and money. That’s why our QC chemists spend time running not just purity checks, but functional group reactivity tests matched to common downstream transformations.
Another difference stands out in shelf stability. Our direct manufacturing experience shows that adding extra electron-withdrawing groups to the core increases shelf life but can reduce water solubility. We monitor these trends by tracking COA parameters sorted by production lot. No customer likes a batch that fails three months before the end of its stated expiry — so we match shipment schedules with real-world applications, avoiding overstock scenarios.
Many of our repeat buyers used to source benzofuran intermediates from aggregators or traders. After several supply hiccups and unclear impurity profiles, they now insist on direct-from-manufacturer supply. The closer relationship enables transparency — precise lot tracing, change control, and the ability to request documentation or in-process data not just for regulatory filing, but as real insurance for their own process qualifications.
We keep a strict internal versioning system for SOPs. Any modification — whether to timing, temperatures, or reagent percent — receives immediate documentation and workforce re-training. Our direct line communication with buyers means feedback runs both ways: if you discover anything unusual, we trace it back to its source and fix it. No runaround, no passing the blame. That’s one reason why we rarely encounter disputes — and why pilot programs often lead to years-long commercial supply relationships.
To us, it’s not enough to provide 3-Aminobenzofuran-2-Carboxamide for a handful of academic projects. Scale-up matters, and scaling brings fresh challenges. Heat transfer, change in crystallization dynamics, and recovery of mother liquors scale nonlinearly. We’ve tackled these upscaling issues by integrating pilot plant trials between kilo-lab and full plant, catching problems like local hot spots, variable solvent partitioning, or unforeseen impurity accumulation.
Real-world scalability means not just collecting a few grams — we handle dozens of kilos at a time, tuning agitators, pumps, vacuum lines, and monitoring pressure changes minute by minute. If a batch doesn’t meet its mark, we chalk it up to process, not people, and make corrections before moving up the tonnage ladder. Only through in-house manufacturing do these lessons hardwire into every shipment that leaves our site.
You might expect a QC lab to function as a gatekeeper, but in our facility, QC operates more like an integrated partner in the manufacturing process itself. Samples come off the reactor, undergo quick crystalline filtering and then hit the spectrometer — not just at the endpoint, but during key steps to catch shifts in intermediate profile or detect over- or under-reaction. We use a mixed panel: HPLC for main peak integration, FTIR for identifying any unexpected peaks, NMR for full structure confirmation, and Karl Fischer for residual moisture — always with cross-validation on secondary instruments when readings seem off.
Routine isn’t always easy. During one hot, humid summer several years back, product yields began to slip, and a minute impurity started showing up at 0.2 percent. Our process engineers worked with QC, traced back the deviation to a drifting environmental control on a storage tank, then modified the transfer schedule to maintain a tighter band on temperature. That season’s lesson led us to upgrade equipment and reinforce our facility’s climate envelope.
Direct production of advanced benzofuran derivatives means waste streams — solvents, filtrates, drying media. Early in our plant’s operating life, we noticed that certain solvents tended to persist in aqueous streams if wash steps weren’t adjusted by season. We built closed-loop recycling for process solvents, clawing back upward of 75 percent in most cycles and reducing our overall treatment burden. Working with in-house analytical teams, we monitor effluent and operate storage for hazardous streams, not simply relying on outside handlers to “deal with” downstream liabilities.
Along with recycling, we document our raw material sourcing for traceability back to primary producers. We address regulatory filings with a focus on full disclosure from raw input through to finished lot — not merely to satisfy an audit, but to ensure we know what goes into every drum and can answer to customers or authorities with clear records.
Every shipment of 3-Aminobenzofuran-2-Carboxamide carries with it a real paper trail — a full Certificate of Analysis, batch genealogy, full process and analytical SOP number references, and explicit impurity profiling data. Not all customers ask for this, but the R&D and production teams who handle regulated intermediates often depend on it. We maintain archives of production records — not just the current year, but going back a decade or more — as some regulatory bodies require long-term traceability for new chemical entities.
We assist clients preparing IND, NDA, or agricultural regulatory filings, supplying not only written specs but live dialogue for questions about synthetic route, impurity handling, or analytical method transference. Once, a customer shifted a process between regulatory regions: US to Europe. Our technical staff worked with theirs, harmonizing analytical tables and cross-walking impurity thresholds as required by both local guidance and ICH standards.
Some producers treat specialty chemicals as static commodities. We’ve learned that both pharma and agrochemical pipelines shift quickly. Lead candidates that looked attractive six months ago may be replaced as new structure-function data comes in. That’s why we maintain a flexible order program for routine and custom-sized batches — small, fast-turn requests for medicinal chemistry runs, or consolidation of multiple lots for greater campaign efficiency in production.
We know from experience that new syntheses, especially using reagents like 3-Aminobenzofuran-2-Carboxamide, often run into the unknown — competing side-reactions, unexpected solubility issues, or the need for a last-minute purity spec change. We keep technical and process staff available to troubleshoot with your chemists, aiming to solve snags with supplier-level insights.
Manufacturing is not static in our world. We monitor and test new synthetic pathways as they emerge in published literature and patent filings. Several years back, a newly developed route offered a more sustainable oxidant and reduced overall waste load. After internal pilot trials, our team reworked the production route, yielding both higher product output and a smaller solvent footprint per kilo produced.
We work closely with research chemists who need specific functionalization, sometimes adapting production to add protecting groups or alter reaction conditions. Direct manufacturing brings the power to adjust on-the-fly, iterate over several campaign batches, and achieve the most reliable results for evolving medicinal or crop protection targets.
Real quality in 3-Aminobenzofuran-2-Carboxamide comes as much from workforce skill as from the hardware used. We’ve kept a stable core of process managers, operators, and analysts for years. Their experience, attention to detail, and willingness to take direct responsibility for each lot’s integrity set our culture. We encourage a mindset that expects feedback and questions from customers — these conversations drive our own improvement.
While some see specialty intermediates as “commodity plus paperwork,” our experience says something different. Skill bred by hands-on practice, familiarity with what downstream chemists really need, and a sense of direct accountability build a better product. Whenever a new issue crops up — unexpected caking in summer, a minor impurity at final isolation — a team member takes up the challenge, isolates the root cause, and makes sure it doesn’t recur next time. Lessons learned feed back into both process documents and the day-to-day practice at the bench.
Over the years, our direct-to-user partnerships have brought consistency and transparency to the manufacture and delivery of 3-Aminobenzofuran-2-Carboxamide. Customers trust our process, not just our paperwork, because they’ve seen the results play out in real projects with real timelines — and a minimum of unwelcome surprises. We invite you to experience a supplier relationship rooted in proven expertise, mutual respect, and solutions that deliver value in the real world of chemical development and manufacturing.
