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HS Code |
857912 |
| Iupac Name | 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine |
| Molecular Formula | C7H7ClN2 |
| Molecular Weight | 154.60 |
| Cas Number | 522606-67-3 |
| Smiles | Clc1ccc2n(CCN2)c1 |
| Inchi | InChI=1S/C7H7ClN2/c8-6-1-2-7-5(3-6)4-9-10-7/h1-3,9H,4H2,8H3 |
| Appearance | Solid |
| Solubility | Soluble in common organic solvents |
| Pubchem Cid | 11709107 |
As an accredited 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams of 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine, with tamper-evident cap and hazard label. |
| Container Loading (20′ FCL) | Standard 20′ FCL holds 10–12 MT of 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine, packed in 25kg fiber drums. |
| Shipping | 6-Chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine is shipped in sealed, chemical-resistant containers to ensure stability and prevent contamination. It is transported under standard conditions, avoiding exposure to moisture and extreme temperatures. Appropriate hazard labels and documentation are included, complying with chemical shipping regulations for safe handling and delivery. |
| Storage | Store 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine in a tightly sealed container, away from moisture and direct sunlight, in a cool, dry, and well-ventilated area. Segregate from incompatible substances, such as strong oxidizers and acids. Ensure appropriate chemical labeling, and access should be restricted to trained personnel with suitable protective equipment. Store according to local chemical safety regulations. |
| Shelf Life | 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine typically has a shelf life of 2–3 years when stored in a cool, dry place. |
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Purity 98%: 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and consistent quality of target APIs. Melting point 120–125°C: 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine with melting point 120–125°C is used in solid-state formulation development, where reliable thermal behavior supports reproducible tablet manufacturing. Molecular weight 168.62 g/mol: 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine with molecular weight 168.62 g/mol is used in structure-activity relationship studies, where precise mass facilitates accurate pharmacokinetic modeling. Stability temperature up to 80°C: 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine with stability temperature up to 80°C is used in chemical storage protocols, where enhanced thermal stability reduces risk of degradation during processing. Particle size <50 μm: 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine with particle size less than 50 μm is used in fine chemical synthesis, where uniform dispersion improves reaction kinetics and product homogeneity. |
Competitive 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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At our plant, batches of 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine come off the line with precision that only years of process improvement can achieve. Watching operators check glass reactors and oversee quality sampling, I can say firsthand that the journey from raw intermediates to this key molecule involves genuine attention to detail and a thorough, hands-on approach that decades of chemical manufacturing teaches. No finish line exists in this business; expectations keep climbing and so do our daily standards.
Molecular formula: C7H7ClN2. The name says plenty, but we think about this material through each measured reaction, the final purity readings, moisture checks, and the record kept on every lot. We always set the minimum assay at 98% by HPLC and watch for color, solid state consistency, and stability over time. Each drum or bottle that leaves our filling room reflects batch data going back to baseline, checked for consistent melting points and residual solvent traces. Those figures are not just numbers filling a certificate; they represent the outcome of chemistry dialed in by people who see the difference strong process makes.
Material handling happens on manageable scales: from analytical to pilot, up to commercial scale in glass-lined vessels and stainless reactors. We pay close attention to headspace conditions, agitation speeds, and pressure differentials between distillation steps. These practical details make the difference between an average batch and material that meets demand with unwavering dependability.
Customers come to us with projects that create new molecules for a host of industries. This compound often appears at that crucial junction where complexity starts for drug candidates or advanced materials. Medicinal chemistry teams rely on this compound as a scaffold for building more complicated heterocycles. Its chlorine at the 6-position turns into a functional handle. Substitution reactions—nucleophilic aromatic or palladium-catalyzed couplings, for instance—begin from this stepping stone. The five-membered fused ring system, containing both saturated and unsaturated nitrogens, gives researchers the flexibility to test new pharmacophores or introduce chemical diversity without backtracking to less stable intermediates.
Seeing universities and biotech clients use our compound in early-stage research never gets old. Some projects chase bioactivity data, others look to create contrast agents or polymers with enhanced solubility. The product’s stability through multiple synthetic manipulations means fewer repeats and less waste—something our chemists appreciate from both technical and practical standpoints.
One lesson that sticks with every batch: consistency matters much more to our partners than flashy new reagents. Chemists want to know the quality on their first order matches what they get in another project run six months later. They need full documentation, impurity profiles that don’t shift, and detailed tracking down to precursor lots. Delivering on these standards pushes us to maintain good manufacturing practices beyond the compliance minimum.
Sample retention has always served us well. Every batch retains backup material stored in temperature-controlled rooms, along with certificates and chromatograms ready for customer or auditor review. We work closely with labs on method validation, reference standard qualification, and troubleshooting—because even the smallest impurity peak can affect a downstream process or analytic readout.
This product’s development drew on real-world learning. Early on, crystallization steps faced precipitation and yield loss unless temperature profiles were fine-tuned. Small tweaks to solvent exchanges led to more uniform granulate and better filtration. Operators shared practical feedback, from sieving mesh adjustments for powder flow to lid design for easier handling.
Few lab methods transfer smoothly to commercial scale, and our teams know this well. Agitation settings must scale cleanly; even a moderate bump in fill height can bring unexpected temperature gradients. We have solved these challenges by incremental trial runs and halted campaigns that didn’t meet our internal targets—even at a cost to timelines or material yield. That’s how our process matured to consistently produce this intermediate at industrial quantities without losing sight of quality.
Samples from each finished lot go through wet chemistry tests as a cross-check to spectroscopy and HPLC quantitation. Manual checks for color, particle size, and visible uniformity play a role in our approval cycle. If a batch shows minor drift from expected visual profile, we halt shipment, verify by reference spectra, and only release with manager sign-off. This remains the rule, not the exception.
The chemistry sector now faces growing scrutiny from regulatory bodies and customers alike. Increased transparency means more demand for detailed impurity profiles, solvent recovery logs, and proof of supply chain security. We’ve welcomed this; each requirement pushed us to improve.
Trace metals, residual solvent, and genotoxic impurity risks receive careful tracking. Our labs run LC-MS and GC-MS scans along with traditional wet chemistry. All production records for this compound remain accessible for full regulatory review, no matter how far back—ensuring that repeat customers and approval authorities get answers fast.
Our operators see firsthand the necessity in solvent recovery and reducing effluent. Waste from pyrrolo[3,2-c]pyridine syntheses includes halide- and amine-rich streams, requiring careful neutralization and separation before discharge. All liquid byproduct tanks get batch-certified for pH and concentration before treatment. Recovered solvents are sent for in-house distillation and reused, trimming raw material costs and reducing carbon footprint for every order.
Continuous review of cleaning agents, filter media, and auxiliary chemicals keeps our process greener each year. Newer membrane systems now assist in wastewater minimization, saving both resources and downstream handling charges. We document every internal change with updated standard operating procedures and environmental impact reports, visible to any customer or regulator who visits our facility.
These process improvements come from staff engagement and active participation from plant chemists, not just on-paper compliance. We consult with R&D and floor managers to trial new separation techniques or greener solvent systems. Feedback from those actually handling the material proves invaluable; it’s the balance between desk-based process design and lived-in experience on the production line.
Customers know too well that switching between suppliers can introduce unexpected headaches. Variation in minor impurity profiles or shifts in physical form can force method changes further downstream. This compound offers one of the more reliable entry points into pyrrolopyridine-based chemistry, delivering a workable balance between reactivity and practical handling.
People using this building block want predictable results with each order. Druggability considerations, library synthesis, or process optimization efforts can’t afford delays or out-of-spec surprises. Because reactivity at the 6-chloro site enables clean coupling or substitution, our material’s uniformity and clarity make downstream work more straightforward for scientists navigating tight project milestones.
We see growing requests from medicinal chemists, custom synthesis teams, and process R&D groups. Each group prioritizes low impurity carryover, good stability over time, and ease of scale when early hits advance past discovery. Our tightly regulated process and document trail supports these needs. Our track record of delivering batch after batch speaks straight to the reliability required by these applications—not just for screening, but for preclinical trials and beyond.
In the crowded field of heterocyclic intermediates, this compound stands apart from related analogues like the unsubstituted pyrrolo[3,2-c]pyridine or other chloro-derivatives at alternate positions on the ring. The unique ring fusion and precise chlorine placement affects both physical properties and downstream synthetic utility. For example, compared to 5-chloro isomers or benzo-fused versions, our 6-chloro intermediate provides a proven route to incorporate substituents at the critical fusion without relying on harsher conditions or accepting higher byproduct loads. This practical reactivity edge allows customers to work up scalable library syntheses and SAR campaigns.
We’ve seen customers trial related fused structures only to return after struggling with purification or insufficient chemical diversity from alternate starting points. Lab teams working with unsubstituted analogues face more tedious functionalization steps. In these cases, the 6-chloro product gives a shortcut: direct substitution or cross-coupling under familiar Pd, Ni, or Cu catalysis. Each trial run on our product comes with in-house support as research teams look to eliminate bottlenecks or replace legacy steps in their own processes.
Handling properties differ too. Other close analogues can bring dustiness, poor flow, or higher clumping, costing time and headaches at the point of transfer and dosing. Over years, operator feedback shaped our approach, reducing fines and static charge issues through incremental blending and improved packaging design. Each process study shows how slight process changes improve drum filling and downstream miscibility, supporting safer, easier plant operations.
Each manufactured lot travels through in-depth screening, including multiple analytical methods (NMR, IR, HPLC, MS). Firsthand observation through all stages—from raw material check-in, through every boost in reactor temperature, to final sample vial sealing—means we catch issues early, never relying on a single test. QA managers review process trends, not just static results, so that the next batch outperforms the last. All documentation can be tied directly to retained samples stored on premises.
Customers auditing our labs or plant floor see that analytical depth running parallel to hands-on scrutiny. Glass containers from each batch store samples under monitored temperature and humidity, ready for retesting at any time. Any shipment query receives not only a certificate but can be traced right back through full lifecycle process records.
We work with customers through every phase of their project—the reality is, unexpected chemistry can always crop up. We’ve assisted on tech transfer, scale-up trials, and purity optimization requests. Over the years, that’s meant sending additional analytical results, discussing minor process tweaks, or giving open access to logs showing variable readings. Our technical teams stand ready, not with stock scripts, but with direct feedback from daily plant experience.
Many customers use our product near the start of custom synthesis campaigns. A stable and reliable physical form avoids caking or irregular mixture, making weighing, mixing, and charging tanks smoother—especially necessary during scale-up runs. We’ve seen clients switch to our form after finding alternate suppliers left unwanted debris, altered color, or batch-to-batch odor changes. By working directly with users, we solved such concerns through tighter moisture controls and refining post-drying steps.
Shipment support matters too. Quick response solves more issues than technical bullet points. If inspection on arrival ever raises red flags—color fade, packing shift, tamper indication—we send backup analysis or replacement without delay. The best endorsement still comes from satisfied clients returning for repeat volumes or recommending our materials to colleagues.
Manufacturing 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine at commercial scale means acknowledging real hazards. Our plant invests in operator training, spill drills, and upgraded pressure release systems. Staff receive regular walkthroughs on emergency procedures, respiratory protection, and direct spill management. We’ve upgraded our containment infrastructure based on hard-won lessons and independent safety reviews.
No substitute exists for on-the-ground vigilance, so our safety managers conduct regular spot checks on both equipment and field logs. Trends in near-miss incidents push continuous improvement. Training files remain up to date and accessible; our retention scores remain above industry benchmarks due to workplace safety standards that prioritize both staff and end-user protection.
History has shown that even minor lapses—spill mismanagement, unchecked temperature increases, or incomplete cleaning—have downstream impacts, not just for us but for everyone handling the finished material. We treat safety compliance not as paperwork but as a daily reality, with team buy-in and ongoing proof of performance.
As chemical industries respond to wider global supply chain pressures, we have to maintain flexible, reliable sourcing and strong partnerships. Our sourcing team keeps long-standing relationships with key raw material vendors. Multi-source qualification provides backup for each intermediate and solvent we consume in this route. Investment in local warehousing and regional finishing centers buffers against transport delays, so end-users avoid stalls and shutdowns.
Forward planning extends to packaging and documentation. Packages are designed for both air and land transport stability, minimizing breakage risk. Complete manifest and regulatory paperwork speeds customs clearance on all continents. Customers working under tight development schedules benefit from predictable delivery and robust support, especially when research windows are short but output expectations keep growing.
Our approach keeps adapting. Plant chemists actively review customer feedback, incorporating suggestions from end-users into future updates. Over time, recurring themes—like physical form changes, documentation detail, and purity assurance—have shaped more than one process revision. Lab and plant teams work together to integrate learning from every batch excursion and customer discussion.
We invest in people, not just process equipment. Training programs encourage both process innovation and safe practice. These efforts have improved both production output and the confidence that each unit of product supports the critical research and scale-up efforts of our clients.
Chemical manufacturing never stands still. From our end, every batch of 6-chloro-2,3-dihydro-1H-pyrrolo[3,2-c]pyridine is produced with direct awareness that it powers tomorrow’s medicines, advanced materials, and discovery programs. Every minor process or workflow improvement represents input from both customers relying on consistency and our committed team of chemical engineers and operators. This constant collaboration keeps shaping a process that delivers today and adapts for tomorrow’s needs.
We recognize why companies return: proven track record, full transparency, and support that goes past generic promises. Our teamwork—from lab bench to full-scale reactors—reinforces a daily habit of betterment. With these habits, we offer more than a product—we offer a partnership built on expertise, reliability, and a useful tool for chemical innovation.
