|
HS Code |
109926 |
| Iupac Name | 2-oxo-2-(1H-pyrrolo[2,3-b]pyridin-3-yl)acetic acid |
| Molecular Formula | C9H6N2O3 |
| Molecular Weight | 190.16 g/mol |
| Cas Number | 105200-37-1 |
| Appearance | Solid (typically powder or crystalline) |
| Solubility | Soluble in DMSO, limited solubility in water |
| Boiling Point | Decomposes before boiling |
| Pka | Approximately 2.0 (carboxylic acid group, estimated) |
| Smiles | C1=CN=C2C(=C1)C=CN2C(=O)C(=O)O |
As an accredited 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical arrives in a sealed amber glass bottle containing 5 grams, labeled with hazard information and batch details for laboratory use. |
| Container Loading (20′ FCL) | **Container Loading (20′ FCL):** 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- securely packed in sealed drums, 20-foot container, moisture & damage protected. |
| Shipping | Shipping of **1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo-** is conducted in compliance with standard regulations for research chemicals. The compound is securely packaged in sealed containers to prevent contamination or spillage and is transported under controlled environmental conditions, typically at room temperature, to ensure stability and safe delivery. |
| Storage | 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- should be stored in a tightly closed container, away from moisture and direct light, in a cool, dry, and well-ventilated area. Keep away from incompatible substances such as strong oxidizers. Store at room temperature (15–25°C). Proper chemical labeling and secure storage to prevent unauthorized access are recommended. |
| Shelf Life | **Shelf Life:** Stored properly (cool, dry, dark conditions), 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- is stable for 2–3 years. |
|
Purity 98%: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures optimal yield and minimal by-product formation. Molecular weight 188.17 g/mol: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- with a molecular weight of 188.17 g/mol is used in drug discovery processes, where it enhances compound specificity during lead optimization. Melting point 174°C: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- at a melting point of 174°C is used in solid formulation development, where it provides stability during processing. Particle size <10 μm: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- with a particle size below 10 μm is used in nanoformulation research, where it improves bioavailability of experimental compounds. Stability temperature up to 120°C: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- stable up to 120°C is used in controlled synthesis reactions, where it maintains chemical integrity under reaction conditions. Water solubility 2 mg/mL: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- with water solubility of 2 mg/mL is used in aqueous formulation studies, where it enables efficient solubilization for biological assays. HPLC purity ≥99%: 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- with HPLC purity not less than 99% is used in analytical reference standards, where it ensures accurate and reliable quantification. |
Competitive 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@bouling-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@bouling-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Work in a chemical plant puts the spotlight on building blocks like 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo-. As direct producers, we watch every step from raw material to purified solid, knowing only careful handling preserves quality and consistency for research teams worldwide. The compound’s structure features the pyrrolo[2,3-b]pyridine core, prized for contributions to pharmaceuticals and advanced intermediates. Production often begins with complex cyclization of starting amines and incorporates oxidative carboxylations that demand fine temperature and solvent control. This sometimes means long shifts monitoring parameters by hand, occasionally tweaking reaction rates in response to instrumentation that reports on color and exotherms instead of solely relying on software. Years on the plant floor teach there is no shortcut to achieving sharp NMR peaks and clean HPLC traces.
Synthetic chemists count on what’s in the drum or bottle — not just what’s on the label. We run batch records and spectroscopic checks because small errors in the pyrrolo ring formation can throw off the entire sequence when downstream, especially with the alpha-oxo side group’s reactivity. Our process always balances throughput with traceability. Customers have asked about polymorph risks, so our team routinely verifies physical forms and reactivity with standard reagents. We learned through experience that transitioning from bench to pilot scale brings new surprises, as cooling rates or mixing can throw off kettle yields. Adjusting those parameters in real time keeps the process on track and the batch within the required purity window.
We supply both research and commercial-scale users. On a kilo scale, greater solvent volumes enhance heat transfer, but require tight control to minimize side reactions. It’s not unusual for project chemists to visit the plant floor, clarifying throughput needs and discussing storage after production. These direct interactions lead to better product, because nothing beats hearing application challenges straight from those who’ll build new molecules on our scaffold. Our people understand timelines matter, and that most customers demand not just speed, but predictable quality that aligns with their own validation protocols. Every bottle of 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- leaves our facility with analysis sheets that show real sample data, not recycled text from other lots. This way, users know that each shipment represents the genuine substance, as backed by our chromatograms and mass spectra.
Most differences between major sources of this compound come down to physical consistency and side-impurity profiles. Through the years, we found nitrogen-rooted by-products hiding as close chemical cousins during reactions. These can be removed thanks to methodical crystallizations and solvent washes, though no shortcut exists to avoid that patient stepwise approach. Even small differences in impurity profiles can influence subsequent chemistry, especially where small-molecule library work or medicinal chemistry optimization depends on high-fidelity scaffolds. Workers on the purification line have gotten used to the sharp but clean aroma of properly handled material — a small reassurance after hours spent tending column rinses and mixed ferments. The true test always comes from the customer’s direct feedback: does their next transformation work, does our lot batch give the expected reactivity?
Supplying 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- means more than bottling a powder. It means having boots on the ground that understand deviations. Operators document each preparation run with care, logging every shift and lot number next to their initials. Even minor drift in solvent composition or reaction time gets discussed in plant meetings. No two lots are exactly identical if production personnel change, and subtle variables have a way of popping up only after several runs. Our team remains vigilant throughout, leaning on years of hard-earned troubleshooting grounded in actual plant operation.
Communication between manufacturing and research is not a one-way street. Early in scale-up, pharmaceutical chemists often highlight where certain side functions carry risks. We have modified our process based on those conversations, dialing in oxidation levels to avoid over-browning and checking thermal decomposition points to head off any instability in shipment. It is common for our lot documentation to include outlier notes documenting where cooling was adjusted or filters swapped, giving transparency that makes for greater trust. Each run brings lessons; sometimes patterns only emerge after several hundred kilograms, such as a recurring minor impurity that correlates to a specific vendor’s starting material. Adjustments get made, not to chase theoretical yield, but to achieve reliable, high-purity product that makes a difference in our customers’ hands.
Handling the product carries its own range of practical concerns. Not all customers have upgraded lines for sensitive alpha-oxo intermediates, so we provide stability reports with real batch history rather than theoretical projections. Years of experience handling this class of compounds means our packagers know to minimize headspace and work with desiccants, always avoiding conditions that spur premature oxidation or unwanted hydrolysis. By giving clear storage advice linked to real observations — not just quoted literature — we protect the value downstream.
Having run hundreds of batches through reactors, our team sees first-hand how minor tweaks in the synthesis of 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- create differences that show up later in customers’ labs. Some rely on robust, multi-step sequences where yield sensitivity remains low, but a surprising percentage require material that can stand up to harsh conditions or be derivatized easily. Our facility is equipped to create custom purities and tailor crystal forms, responding to precise requests that average distributors cannot meet. Plant staff have learned to recognize subtle cues — a smell, a shift in viscosity, a faint difference in color — that indicate the process has drifted off spec. Real experience gives us an edge, since we’ve seen the pitfalls of skipping process steps to chase raw yield at the expense of purity or shelf stability.
Even something as routine as filtering a crystallizing slurry can cause headaches when working with this compound. The alpha-oxo group shows a penchant for picking up moisture. Rushed packaging risks introducing micro-impurities that grow during storage, undermining consistent downstream chemistry. Our packaging team logs each drum’s humidity readings, with the senior technician verifying all lots by routine Karl Fischer titration on random samples. These quality practices have kept our customer claims rate extremely low, allowing researchers to trust that our lots will reproduce past results reliably, even with the increased scrutiny many regulatory agencies now demand. Chemical space moves fast, so reliability and transparency matter as much as price.
We know many researchers have run into supply inconsistencies — different batches from the same supplier showing measurable changes in reactivity or color. Often these problems arise not from raw material itself, but from inconsistency on the production floor: a minor contamination in one batch, an improperly dried filter cake, or subpar purification. Such issues show up only under tight QC regimens, but researchers see the effects in costlier repeat reactions or troubleshooting time. We address complaints by inviting clients to audit our lines, check our test logs, or even send their own monitoring specialists to walk the floor and sample bulk product. Over the years, that model of open doors and knowledge-sharing has helped us win repeat orders even as competitors cut corners; no one wants unexpected “learning moments” at scale-up.
Buyers approach us with diverse ideas for 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo-. Many want the pyrrolo core as a scaffold for medicinal chemistry, synthesizing small-molecule libraries meant for kinase inhibition or signal pathway modulation. Some focus on modification at the acetic acid group, adding complexity for advanced material science or combinatorial libraries. The alpha-oxo function enables direct coupling or serves as a lynchpin in constructing more elaborate heterocycles. Academic and industrial users come back year after year, citing the reproducibility of their downstream couplings, condensations, or derivatizations on our lots. Our production runs produce material with narrow impurity profiles and consistent melting points, qualities that matter far more to researchers iterating on multi-step syntheses than generic claims of “high purity” offered by brokers.
Process development chemists have told us stories of how small deviations in quality or moisture content of starting materials delayed timelines and jeopardized pilot plant product. Working in a regulated space, some even send us their own target impurity specs, seeking pre-approved quality thresholds. Real production means adapting — we set up guided runs under observation and tweak crystallization or drying parameters to align with those needs. On occasion, we have split lots mid-process to accommodate two distinct research teams with divergent requirements, delivering custom forms or packing densities tailored not to the market average but real researcher workflow.
The main difference offered by direct manufacture is transparency. Testing doesn’t just happen at “the end” of the process. We sample at every stage: starting material, reaction intermediates, final bulk, and after packing. Production staff interpret the spectra, not just a faceless QC team. This practical engagement — stirred into every phase from planning to shipment — pays off in stronger lots and enduring relationships. When customers call with troubleshooting requests, they speak directly with staff who ran the batch, remembered oddities, and can offer advice grounded in personal hands-on experience. Reliability in specialty chemicals — especially ones destined for high-stakes synthesis — comes from the diligence of real operators, not automated systems or distant commercial departments.
Years of direct experience have taught us that differences aren’t just academic — they matter in start-up labs and scale-up facilities alike. Different sources of this compound ship varying physical characteristics: powdery, somewhat hygroscopic, prone to clumping, or hard compact cakes. Each trait stems from the details of process control, filtration, wash, and drying. Some sources cut steps, leading to color variegations or undetected micro-impurities that complicate clean downstream transformations. Pure product, with few impurities and no hidden water, brings more predictable reactivity and longer shelf-life under recommended storage.
Our team has received calls from researchers who experienced failure due to trace impurities, learning that not all material labeled with the same name behaves the same way during subsequent reactions. We work with project chemists to analyze the failed outcomes, running side-by-side trials with our own batches to reveal where a competitor’s less careful drying or incomplete purification caused problems. These real-world lessons emphasize why meticulous manufacture at every stage and real transparency about actual impurity levels benefit users far more than claims made without evidence. Replication and documentation, backed by actual chromatograms and physical logs, help researchers avoid costly unwelcome surprises.
For us, the clock never stops at “product shipped.” Our support often continues through email and direct calls, where customers describe difficulties or out-of-range observations. Plant experts debug issues by asking targeted questions rooted in our experience, drawing on production logs or trial samples reserved for these scenarios. Our knowledge base reflects hands-on corrections already performed and real-life challenges overcome. We never outsource this engagement to a third party who lacks context, and our customers have come to rely on this practical “extra mile” approach as part of our value. Newer chemical facilities, after struggling with repeated product failures, have shifted over to our batches — sometimes at a premium — because tainted starting material always costs more in the long run.
Manufacturing 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo- isn’t finished after one successful lot. We log every run, noting where yield drifted or purification rates changed based on subtle upstream influences such as ambient temperature or container supply changes. Customer feedback — positive or critical — steers us toward better clarification filters, new drying regimens, or alternate packaging materials. By maintaining this culture of open review, from incoming RM inspections to shipment tracking, we catch weak points while they are still manageable. Recent investments in analytical equipment have improved our profiles for both known and unknown impurities, keeping standards high and customer complaints rare.
Operators undergo routine retraining, learning to spot emerging problems before they disrupt supply or compromise user work. We conduct internal audits that check both process stability and proper documentation procedures. By keeping documentation tied directly to the plant floor, we foster a sense of ownership and accountability in every member of the production chain. This focus on transparency, reinforced by customer audits and certifications, sustains the confidence buyers place in us during high-stakes phases like regulatory filing or upscaling.
As global standards for chemical manufacturing grow stricter, we’ve adopted a proactive approach to environmental and safety controls — not because auditors require it, but because long-term operations depend on healthy practices. Treating waste responsibly, reducing solvent emissions, and monitoring operator exposure aren’t optional for us. Plant safety committees meet regularly, and lessons learned from each campaign are rolled into fresh SOPs, keeping both product and people safe. The best chemical supplies don’t just meet industry minimums; they come from operators who care about the process and the future.
Research success starts with raw material reliability. Our customers include early-stage drug teams and research institutions whose discoveries depend on robust, reproducible starting points. We don’t take shortcuts. Instead, our entire manufacturing approach — from raw purchasing to final QC — is anchored in transparency, hands-on expertise, and respect for both process and user. By constantly investing in equipment, training, and open communication, we keep building reliability into every lot shipped.
Working with 1H-pyrrolo[2,3-b]pyridine-3-acetic acid, alpha-oxo-, we have seen the challenges and successes that define real chemical manufacturing. Each improvement to the process, each adjustment for a unique application, and each open conversation with our customers pushes us to deliver the substance as more than just a raw material — it’s a foundation for pushing boundaries in science and technology. Our experience is built batch by batch, backed by years on the production floor, guided by the actual needs of those who depend on uncompromising quality every time they open a new container.
