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HS Code |
914683 |
| Chemical Name | 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde |
| Molecular Formula | C8H6N2O |
| Molecular Weight | 146.15 g/mol |
| Cas Number | 1256359-09-3 |
| Appearance | Light yellow to brown solid |
| Melting Point | 92-96°C |
| Smiles | C1=CN=C2C(=C1)C=CN2C=O |
| Inchi | InChI=1S/C8H6N2O/c11-5-6-3-4-10-8(6)7-2-1-9-7/h1-5,9H |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Purity | Typically ≥ 95% (supplier dependent) |
| Storage Conditions | Store at 2-8°C, protected from light and moisture |
| Hazard Statements | Irritant, handle with gloves and eye protection |
As an accredited 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 5 grams, tightly sealed, with hazard labeling and chemical identification: "1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde, CAS# 944676-86-4." |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde involves safe, efficient bulk packaging, maximizing cargo space and minimizing contamination. |
| Shipping | 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde is shipped in tightly sealed containers, protected from light and moisture. Standard chemical shipping practices apply, with appropriate labeling and documentation. The package complies with local and international regulations for transport, using cushioning material to prevent damage. Temperature-sensitive handling may be required depending on storage recommendations. |
| Storage | 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight and incompatible substances such as strong oxidizers. Store at room temperature and protect from moisture. Ensure labeling is clear and use appropriate secondary containment to prevent spills or leaks. Follow all relevant safety and regulatory guidelines. |
| Shelf Life | 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde should be stored cool and dry; typical shelf life is 1–2 years if unopened. |
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Purity 98%: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal by-product formation. Melting Point 157–161°C: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde with a melting point of 157–161°C is used in medicinal chemistry research, where controlled recrystallization is achieved for optimal compound isolation. Molecular Weight 158.15 g/mol: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde at a molecular weight of 158.15 g/mol is used in heterocyclic compound development, where precise stoichiometry enables reliable reaction predictability. Stability Temperature up to 85°C: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde stable up to 85°C is used in chemical process engineering, where thermal resistance facilitates safe handling during synthesis. Particle Size < 10 μm: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde with particle size below 10 μm is used in advanced material formulation, where uniform dispersion improves product consistency and activity. Moisture Content ≤ 0.5%: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde with moisture content no more than 0.5% is used in organic electronics synthesis, where low water content prevents unwanted side reactions. Solubility in DMSO: 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde soluble in DMSO is used for high-throughput screening assays, where enhanced solubility results in accurate compound delivery and dosing. |
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For years, process chemists and research labs across pharmaceutical and agrochemical sectors have reached out to manufacturers for reliable intermediates, and among those, 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde stands out for its role in heterocyclic synthesis. With over a decade invested in scaling up its production, direct hands-on experience has shown that consistent batch quality determines the outcome in target molecule synthesis. There is a fine balance between purity, yield, and process safety, and this compound brings its own daily lessons to the factory floor.
When scaling up to multikilogram batches, the control over every stage is not just about ticking quality boxes—it's about enabling each partner chemist to move forward confidently after every reaction step. This product brings particular challenges with sensitivity to moisture and air, and manufacturing teams maintain rigorous environmental monitoring around both raw material handling and product packaging.
Differences in batches made at pilot and then at full-production scale reveal themselves in critical quality parameters. As a manufacturer, close eye goes to melting point, NMR verification, moisture content, and appearance, all downstream impacts from fine-tuning process controls within every reactor run. The nuances often disappear in datasheets, but ground-level work recognizes that an unexpected impurity profile creates headaches in a medicinal chemistry program. Avoiding lot-to-lot drift, especially in aldehyde content and side-product suppression, demands constant attention rather than automation alone.
Typically, requests center on 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde with HPLC purity well over 98%, and most partners specify water content below 0.5%. Each drum leaves the plant after hands-on sampling and testing, not through remote or third-party hands. Many clients ask for documentation on polymorphs or stability profiles, especially those pursuing long programs. In response, extra stability testing across warehouse seasons and variable humidity has become standard. This feeds back directly into packaging methods and storage instructions.
Across hundreds of production runs, the biggest differences from resale sources come down to transparency and reliability. Direct manufacturing provides scope for customizing lot size, tailored drying conditions, and alternate solvents in crystallization. Remote traders rarely assist with on-the-fly adjustments or share in-process information. When an unforeseen process deviation arises, direct access shortens feedback loops; chemists can reach us, share the problem, and receive real process data rather than marketing scripts.
Choosing how to approach the manufacture of this heterocyclic aldehyde pushes us to keep learning from each reaction. For example, working with continuous flow methods rather than classic batch synthesis has opened ways to better control exotherms and lower impurities, especially in the sensitive formylation steps. The largest R&D investment has been channeled into optimizing crystallization strategies, targeting faster separations with less solvent waste.
Downstream, direct control lets us experiment with new drying processes—blending traditional vacuum oven techniques with controlled nitrogen flow. Some customers attach particular value to powders that flow freely in dry rooms; others need product that packs densely for storage. As the actual manufacturer, feedback from real-world process bottlenecks or stability surprises directly shapes the next round of process improvements.
Supplying this compound reveals where theory and shop-floor reality diverge. The aldehyde moiety is sensitive, liable to water uptake, and prone to slow oxidation under air. This leads to practical issues, including caking, slow color changes, and traces of acid at prolonged storage. Working with suppliers as a direct source rather than through intermediaries improves shelf life and reduces these headaches. Over years in the industry, we've moved from generic foil bags to triple-layer, nitrogen-flushed packs that reach chemistry groups without the discoloration or degradation that haunts less-controlled logistics.
Another lesson well learned: when a chemistry group calls to say a batch is “off spec,” our in-house team responds by digging into both archived QC results and environmental monitoring logs. This level of traceability is built into our process controls from the raw material stage onward, and direct manufacturer relationships cut through the confusion that’s common with third-party routes. We have seen projects nearly stall because small shifts in aldehyde purity or minor color changes pushed intermediates out of specification—tight process control makes or breaks deadlines for both sides.
Time after time, research chemists note the unpredictability of material sourced through distributive channels. Real differences arise not only from the lack of current batch data, but also from varying storage histories, repacking, and shipping conditions. Direct procurement means assurance: the product delivered matches agreed specifications from primary manufacture, with all supporting analytical data available before any order is shipped. On top of that, production chemists respond to scope for special requests—whether aimed at impurity reduction for late-stage intermediates, or specific particle size controls for pilot plant runs.
It is not unusual for direct customers to request adjustments following their own in-house trials. Sometimes this means tighter limits on specific trace impurities, or a change in solvent residue cutoffs to meet regulatory needs—especially for GMP-bound development work. Manufacturing teams engage with these requests in real time, drawing on both archived batch records and current in-process data, something impossible in a commodity brokerage relationship. More often than not, partnership with end users brings previously unconsidered improvements—from custom handling instructions, to changes in QC protocols that enhance both usability and final formulation success.
End users draw most of their 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde for advanced synthesis, especially in drug development, agrochemical research, and fine chemicals. This molecule’s fused heterocyclic core brings value as a building block in kinase inhibitor programs, blockbuster crop-defence compounds, and diverse materials science explorations. From the vantage point of production, requests often reflect a sector’s emerging challenges—new drug candidates drive demand for ever-tighter impurity profiles, or shifting regulatory rules push for faster access to comprehensive trace analyses.
Long-term supply relationships contribute both to project success and technical advances. For example, integrated feedback on performance in high-throughput screens or pilot GMP campaigns comes back to our process teams. We have seen several partners share reaction bottlenecks involving subtle differences in aldehyde reactivity. Every time a synthesis step or formulation process stalls, we dig in, analyze the impurity pattern, study stability curves, and adjust upstream production—something no trader or third-party warehouse offers at any scale.
Routine manufacturing work brings close encounters with the challenges researchers face. Regularly, we field calls from process chemists developing scale-up routes, and their insights drive iterative improvements. One repeated concern centers on the impact of oxygen or trace water on downstream reactions—a risk that becomes all too real if the packaging falls short or shipping lags. In response, we invested in specialty packaging processes, including direct nitrogen flush and onboard oxygen scavengers, to help preserve product integrity through the last mile of distribution.
Scaling up for kilogram- and ultimately ton-scale orders, process optimization efforts concentrated on minimizing residual metals, tightening both aldehyde recovery and side-product identification, and providing more granular analytical profiles. This “boots-on-the-ground” experience created a feedback cycle: every anomalous analytical pattern reported from downstream partners went straight to engineering and QC for review.
Over several production cycles, we moved from basic batch records and COAs to detailed impurity tracking, assay methodology updates, and collaborative troubleshooting guides developed hand-in-hand with end users. Each iterative improvement carried a story, often emerging from real shipment mishaps, late-night troubleshooting calls, or unanticipated formulation hurdles encountered by our partners.
Direct manufacturing enables transparency rarely possible via intermediaries. Each consignment leaves the facility with a complete analytical record—NMR, HPLC, moisture, and stability profiles—often tailored for the exact destination, as requested by researchers. This practice started out of necessity: more than one early partner flagged variation in off-the-shelf material, especially as aldehyde sensitivity is high. From there, open data sharing became standard, not exception.
We frequently send reference spectra, historical QC data pools, and process logs alongside shipments, enabling recipient chemists to benchmark their in-lab findings against source plant records. Rapid response to technical queries, requests for historical batch context, and troubleshooting advice distinguishes manufacturing engagement from commoditized trading.
With larger clients, joint development sessions remain routine, focusing on understanding how trace impurity drift, physical granularity, or even minor packaging flaws affect project pacing. Direct access to process and analytical teams keeps technical support real and immediately accountable. These technical partnerships seeded trust, paving the way for more robust supply chains and faster resolution during the unexpected.
1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde produced direct from the source comes with traceability and process insight. Unlike surplus or re-packed stocks, the genuine article traces batch lineage, process modifications, and raw material origins. Quality differences revealed in long-term stability data, discoloration trends under accelerated storage, and analytical reproducibility separate firsthand product from generic supplies.
Over numerous campaigns, direct producers field requests for specialized grades—tighter particle-size range, specific polymorphic forms, and solvent-free lots. Manufacturing teams respond with customized processing, guided by frequent laboratory check-ins after delivery. End users benefit from access to upstream analytical data and frontline advice for preserving and handling the sensitive aldehyde group through multiple research or scale-up phases.
Feedback from medchem teams and process engineers consistently highlights the difference in project outcomes when traceable, high-integrity batches enter advanced research or regulatory submission phases. This reliability turns into faster progress and more predictable success versus competing sources where product histories blur between resellers, repackers, or old shelf stocks. The lasting result is a closer, more responsive relationship with chemists and R&D groups who understand the value of manufacturer-direct supply.
Throughout ongoing collaborations with academic, biotech, and commercial research facilities, direct manufacturer supply of this molecule has enabled multiple breakthroughs—enabling rapid SAR exploration, GMP campaign readiness, and even custom pilot-batch support for regulatory filings. Each season brings new challenges, from evolving environmental regulations to demands for reduced solvent use or tighter waste profiles. On each front, rapid manufacturer response accelerates both compliance and innovation, feeding new data back into everyday process improvements.
Every manufacturing partner recognizes familiar project curves: unpredictability in exploratory chemistry, late-breaking optimization needs, and shifting safety requirements. Direct access allows for flexible order sizes, technical consultation, and fine-tuning specifications before the first kilo leaves the plant. Researchers with urgent timeline or data-driven questions regularly bypass indirect channels, reaching plant chemists for expedited solutions and adjustments.
This cycle of transparency and real-time support delivers both peace of mind and measurable project gains: faster turnaround on new requests, fewer experimental dead-ends, and faster pathfinding toward regulatory greenlights in the competitive pharmaceutical and chemical landscape.
Manufacturing 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde is not a static process but one of continual learning and adaptation. Each batch presents a new opportunity to analyze, learn, and refine both upstream chemical processes and downstream handling. Hands-on production teams absorb new analytical techniques, trial alternative synthesis routes, and investigate stability across packaging materials and warehouse conditions. End user input sharpens each stage, revealing pain points and optimization opportunities unlikely to surface in third-party sales chains.
Plant operations also invest in worker training and cross-disciplinary problem solving. For instance, when trace decomposition products caused batch failures in a partner’s catalyst screen, coordinated review between plant QC, analytical chemists, and logistics returned an actionable fix in under a week. Such quick learning cycles arise from mission-driven communication between manufacturer and customers, bypassing the data lags typical with warehoused, redistributed chemicals.
Routine post-delivery check-ins catch unexpected issues, from packaging seam failures in export shipments to unexpected crystallization shifts during transit. Direct feedback ensures rapid corrective action, improving both process reliability and relationship strength for subsequent orders.
In an environment where every competitive edge can affect research speed or regulatory approval, direct manufacture and support make a substantive difference for labs relying on 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde. Decades of practical experience, coupled with real feedback from process-side users, drive the continuous evolution of both product quality and technical service.
The richest lessons trace back to daily plant routines—supervising moisture load during final drying, verifying in-person every batch appearance, and cross-checking analytical drift across campaigns. These day-to-day practices create the supply stability that allows chemists to focus on discovering, optimizing, and producing new materials—not troubleshooting material inconsistencies or sourcing uncertainties. As industry pivots toward more complex heterocyclic scaffolds and demanding regulatory oversight, this compound remains a touchstone for what direct manufacturing expertise means in science-driven industries.
Choosing a trusted, direct manufacturer for 1H-pyrrolo[2,3-b]pyridine-4-carbaldehyde is about more than materials on a shelf—it is about building resilient scientific partnerships. Ongoing improvements, user-driven adjustments, and transparent analytical sharing lay the groundwork for more successful research, robust scale-up, and long-lasting chemical supply relationships. The combined effort of manufacturer and scientist ensures not only better molecules, but also faster, more confident progress in the projects that matter most.
