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HS Code |
688848 |
| Product Name | 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine |
| Molecular Formula | C7H8N2 |
| Molar Mass | 120.15 g/mol |
| Cas Number | Unavailable |
| Appearance | Colorless to pale yellow liquid |
| Solubility In Water | Slightly soluble |
| Chemical Structure | Heterocyclic compound with fused pyrrole and pyridine rings |
| Smiles | C1CNCC2=CN=CC=C12 |
| Inchi | InChI=1S/C7H8N2/c1-2-7-5-8-3-6(7)4-9-1/h1-2,8-9H,3-5H2 |
As an accredited 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging for 6,7-Dihydro-5H-Pyrrolo[3,4,6]pyridine (1g) is a sealed amber glass vial with a tamper-evident cap. |
| Container Loading (20′ FCL) | 20′ FCL container holds securely packed 6,7-Dihydro-5H-Pyrrolo[3,4,6]pyridine drums, ensuring safe, efficient, and contamination-free transportation. |
| Shipping | 6,7-Dihydro-5H-Pyrrolo[3,4,6]pyridine is shipped in tightly sealed containers to prevent moisture and air exposure. It is transported according to chemical safety regulations, with appropriate hazard labeling. The packaging ensures stability during transit, and all handling complies with local and international guidelines for the shipment of laboratory chemicals. |
| Storage | 6,7-Dihydro-5H-Pyrrolo[3,4,6]pyridine should be stored in a tightly sealed container, protected from light and moisture. Keep it in a cool, dry, well-ventilated area, preferably at room temperature or as recommended by the supplier. Store away from incompatible substances such as strong oxidizers. Ensure proper labeling, and limit access to trained personnel. |
| Shelf Life | 6,7-Dihydro-5H-pyrrolo[3,4,6]pyridine should be stored cool, dry, protected from light; shelf life is typically 2 years unopened. |
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Purity 98%: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine with 98% purity is used in pharmaceutical intermediate synthesis, where high purity ensures optimal reaction yield and minimal byproduct formation. Melting Point 140°C: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine at a melting point of 140°C is used in organic electronics fabrication, where thermal stability supports consistent thin film formation. Molecular Weight 120.15 g/mol: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine featuring a molecular weight of 120.15 g/mol is employed in medicinal chemistry research, where precise stoichiometry enhances compound screening accuracy. Particle Size <10 µm: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine with a particle size less than 10 microns is used in solid dispersion formulations, where improved dissolution rate increases bioavailability. Stability Temperature 80°C: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine with an 80°C stability temperature is utilized in agrochemical formulations, where enhanced thermal resistance maintains formulation integrity during processing. Assay 99%: 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine with a 99% assay is used in analytical reference standards, where high assay guarantees reliable calibration and traceable analytical results. |
Competitive 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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On the factory floor, staring at a reactor with dozens of controls and lines for different raw materials, you look for substances you can count on. Our business lives and dies by the reliability of these materials. Over years, a compound like 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine has become a mainstay on our site, requested consistently by teams working on projects from pharmaceutical research to developing new classes of materials.
This molecule, with its unique fused ring structure, attracts attention from chemists developing heterocyclic building blocks. Our most experienced process engineers enjoy working with it because the consistency in scale-up gives predictable results batch after batch. When a new customer asks for process advice, our technical team relies on years of hands-on production knowledge rather than reading through second-hand reports or copied data sheets.
The purity and physical characteristics of 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine influence more than just paperwork. Here, we monitor parameters like melting point, moisture, and trace impurities because downstream failures cost precious time. Our current production model delivers the material with a minimum purity of 98 percent, validated using HPLC and backed up with NMR runs from both batch release and periodic cross-checks.
A while back, we faced an issue where a small change in a solvent led to an unexpected impurity that affected crystallization downstream. Most clients did not notice, but one customer caught it in their application lab and let us know. We remembered the night shifts our operators had pulled to isolate the variant, and we dug through our records. By collaborating with this user's team, we pinpointed the source and then adjusted our distillation process. Since then, we have kept extra internal reference standards on hand to catch any drift. This kind of feedback loop between production and customer is possible because we, as the manufacturer, stay close to the process. Third-party suppliers struggle to offer that level of detail.
Several years back, the pharmaceutical discovery group visited us to discuss our capabilities for supporting advanced heterocycle synthesis. They asked tough questions about scale-up, chiral purity, and control of byproducts. Our chemists showed off our years of process optimization, demonstrating that our 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine performs solidly even under demanding coupling and ring expansion reactions. Other users, designing new ligands for catalysis, have found our material adaptable because they know exactly what to expect from a constant supply.
One of the key features of this compound comes from the placement of its nitrogen atoms and the reduced six-membered ring. The difference in electron density and steric demands, compared to other similar fused heterocycles, can shift reactivity by enough to open new reaction windows in both academic and commercial applications. We have shared kinetic and reactivity studies with several long-term clients so that they could fine-tune their experimental conditions. As a manufacturer, sharing these insights goes beyond routine quality control; it creates collaborations that teach all of us how to extend the chemistry.
Our technical team fields requests for similar compounds on a regular basis, such as hydrogenated pyridine derivatives or other fused bicyclic amines. Most of these candidates either introduce extra synthetic steps, come with more complicated waste profiles, or fail to offer the same selectivity in target reactions. We have seen customers trial alternatives for rapid cost reduction, only to find lower yields or more challenging purification during scale-up. Our 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine represents a balanced solution: accessible enough to guarantee supply, but not so generic as to flood the market with inconsistent grades or mystery contaminants.
We chose this compound for our portfolio after pilot studies revealed manageable byproduct streams and reliable yields with diverse starting materials. We operate reactors capable of handling batch or continuous production, so output adjusts to demand without relying on spot buying from outside brokers. Control over process parameters means we can respond directly to special requests: for instance, if a customer requests a specific particle size or an even tighter residual solvent range, we have the flexibility to revalidate and ship a lot that matches. You are not talking to a warehouse; you are dealing with engineers and operators who touch the product every day.
We have seen some misunderstandings in the market about products like 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine. Some believe that such building blocks act as commodities, with little difference between manufacturers or supply chains. Janice from our analytics group likes to point out that comparing the same CAS number from different sources does not guarantee the same performance in target syntheses. Not long ago, a customer experienced repeat failures in a Suzuki coupling step. They approached us to test our batches in parallel and reported a meaningful improvement: not only better yields but also cleaner profiles on both LCMS and NMR. They traced this to lower levels of isomeric byproducts and more predictable handling in their solvent system compared to what they had sourced from aggregators.
Researchers often need a balance between reactivity and stability. Many of our clients use this molecule as a quick entry point into drifted polycyclic frameworks, opening pathways for diverse pharmaceutical scaffolds, specialized ligands, and even precursor blocks for agrochemicals. We find particular value in the smoothness of standard transformations like amide coupling, electrophilic substitutions and metallation reactions when using material born in our own reactors.
Quality to us means more than ticking off a spec sheet. We track water content with Karl Fischer titration at every batch, because we have seen reactions fall apart from a few tenths of a percent excess moisture. Every drum and flask is nitrogen-purged before sealing, since pickup of oxygen can kick off slow degradation over weeks. When delivering to a customer running a tenacious peptide coupling, we have sometimes made custom shipments within hours, tapping into our on-site logistics team.
A lot changes on a production line from one season to the next. Even small fluctuations in temperature or solvent purity creep into the final product. Our team tracks these variables with eyes on long-term traceability. Unlike generic traders, who ship barrels based on lot codes and spot market availability, we manufacture each batch with full control over every stage. We train our operators to recognize anomalies—a slight shift in color, a trace of off-odor—and to halt transfer if results look off-spec. Stories of supply chain failings fill the news each year, usually because someone somewhere did not watch a process closely enough.
Some competitors subsist by reselling excess stock with minimal checks beyond standard paperwork. We operate differently. Each customer query is answered by staff who know the material. Our technical group does not rely on third-party lab certification alone; they routinely replicate customer processes in-house to ensure support goes beyond generic answers. We invite customers to visit or send auditing teams for real-time confirmation and process walk-throughs. This open-door, hands-on approach creates a feedback culture which, over time, improves both safety and performance—for us and for those relying on what we ship.
Our founders set up the facility with flexibility and scale in mind, based on years of direct industry experience rather than spreadsheets and PowerPoint slides. From raw material sourcing to waste management, every piece of the operation aims at long-term relationships instead of just one-off deals. Most team members have worked up from entry-level roles, bringing direct know-how to every shift. We see strong retention rates over a decade because our people find pride in the actions that affect every batch.
Several chemical intermediates appear in our catalog, yet 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine generates the most technical correspondence with users from both pharma and materials science. Customers looking for reliable scale-up partners often ask about real-world performance, issues with transporter controls, or nuances in packaging and storage. We reply from experience, not theory. More than half of our best ideas for packaging upgrades or alternate purification tweaks have started with a field report or phone call, not a regulatory directive.
Protecting chemical quality after production is as demanding as synthesis itself. 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine does well under dry nitrogen, but we do not rely on old habits. Each lot ships with sealed liners and tamper-evident closures, chosen after receiving feedback on damaged drums during earlier years. For our most sensitive users, such as those developing new actives under tight confidentiality, we have arranged custom pack sizes and discrete deliveries. Deliveries here do not just leave our gate on a truck; we stage regular temperature and humidity checks until your order gets to your door, monitored by our in-house logistics crew.
We keep detailed records of shipping temperatures and pressures, so if a client comes back with an application snag, we trace any possible transport effect right down to the time-of-day. This beats spreadsheet tracking by a mile, because every operator can get the exact delivery record from our integrated production-to-shipment system. This way, downtime gets resolved with real data, not finger-pointing.
We do not sit still. Our technical staff arrange periodic retrospectives where we sit down and dissect any unexpected result or discrepancy at length. Last winter, during a challenging period of raw material shortages, we pulled the production unit leads together for a full week to stress-test alternative supplier routes for our key intermediates. This revealed not only new backup vendors but also subtle benefits in tweaking certain steps, allowing us to improve flux and consistency without sacrificing purity.
Routine does not last in chemical production. A few years ago, an atmospheric vent calibration malfunctioned, letting in a microcurrent of air to the reactor. We caught an unusual peak in one of the final product NMR scans, rejected the batch, and spent two nights recalibrating every vent monitor. That attention to detail becomes ingrained when you do not have a distant headquarters or a buyer-seller wall separating you from your product stream. We build these lessons into SOPs and then bring customer lessons back for the next revision.
Researchers working at the edge of chemical knowledge often look for subtle differences in starting materials to influence everything from catalyst behavior to biological binding. Having a manufacturer as an engaged partner gives an edge in reproducibility and customizability. Many collaborative projects have started with a quick call or an experimental request. We set up custom process windows or unique impurity profiles for pilot runs, always with the understanding that tomorrow’s compound could demand a fresh approach. Academic partners appreciate our openness about failed reactions or tricky purification insights, as we keep no secrets about side reactions encountered or quirks in intermediate isolation.
Our track record with innovation grants and industry collaborations means we keep a close eye on regulatory movement and intellectual property boundaries, without trading off the flexibility to adapt batch-to-batch for client needs. This spirit of mutual trust and problem-solving sustains our approach to specialty chemical production.
Specialty heterocycles such as 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine do have their quirks. Some scale-up users have cited sensitivity toward basic or acidic conditions in certain downstream reactions. Rather than ignoring these pain points, we offer bench-scale trial runs, gathering data at real volumes and sharing those files with technical partners. Logistics across long distances pose their own headaches, and for clients with especially tight temperature control requirements, we work out refrigerated shipments or rapid turnaround for just-in-time delivery.
On the environmental side, our process waste streams use continuous monitoring, and we invest part of our capital spending each year on new solvent-recovery units to minimize environmental impact. Our team welcomes outside audits and regularly hosts local regulators for walk-throughs, a level of transparency that has benefited everyone involved. Not every supplier can, or wants to, offer this level of visibility or adaptability.
Most customers stay with us for more than a single project. The most common feedback we hear relates to responsiveness and practical advice, not to paperwork. When a client launches a tech transfer or a new analog, our production and technical staff stay engaged until success. A long-running partnership with a US biotech resulted in a new isolation protocol last year, which we now use as a template for similar projects globally.
Direct contact with the manufacturer cuts out weeks of guesswork, as our teams speak from daily interaction with the materials, the reactors, and client processes. This constant hands-on approach, tested by years on the factory floor, gives every batch of 6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine a quality signature you can trust for your next synthesis, scale-up, or process development run.
6,7-Dihydro-5H-Pyrrolo[3,4,6]Pyridine stands out not because it is rare or impossible to find, but because behind every shipment comes a production story anchored in vigilance, real-world experience, and a determination to offer more than just specifications on a page. We know its value because we have labored over every kilogram, listened to the scientists who push its chemistry forward, and sweated the details that matter in both the plant and the lab. This is not a warehouse product with a stock code; it is a backbone to research that demands reliability, perspective, and pride in the making.
