|
HS Code |
791941 |
| Iupac Name | 2-(Propan-2-yloxy)pyridine-3-carbaldehyde |
| Cas Number | 6708-61-6 |
| Molecular Formula | C9H11NO2 |
| Molecular Weight | 165.19 g/mol |
| Appearance | Yellowish liquid or solid |
| Boiling Point | Unknown, but estimated >200°C |
| Melting Point | Unknown |
| Density | Approx. 1.11 g/cm³ (estimated) |
| Purity | Typically ≥98% |
| Solubility In Water | Slightly soluble |
| Flash Point | Estimated around 110°C |
| Smiles | CC(C)OC1=NC=CC(=C1)C=O |
| Inchi | InChI=1S/C9H11NO2/c1-7(2)12-9-8(6-11)4-3-5-10-9/h3-7H,1-2H3 |
| Refractive Index | Estimated around 1.54 (20 °C) |
| Storage Conditions | Store at 2-8°C, in a tightly sealed container |
As an accredited 2-Isopropoxypyridine-3-carboxaldehyde factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 10g 2-Isopropoxypyridine-3-carboxaldehyde is packaged in a sealed amber glass vial with tamper-evident cap and hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Isopropoxypyridine-3-carboxaldehyde involves secure, compliant packing in drums/containers, ensuring safe bulk chemical transport. |
| Shipping | 2-Isopropoxypyridine-3-carboxaldehyde is shipped in tightly sealed containers, protected from light and moisture. Standard shipping methods for laboratory chemicals are used, including secondary containment and appropriate hazard labeling. The package complies with local and international regulations for chemical transport to ensure safe and secure delivery. Temperature control is provided if required. |
| Storage | 2-Isopropoxypyridine-3-carboxaldehyde should be stored in a tightly sealed container, in a cool, dry, well-ventilated area away from direct sunlight, heat sources, and incompatible substances such as strong oxidizers. Keep the storage area free from moisture and ignition sources. Ensure proper labeling and handle under a fume hood to avoid exposure to vapors. Use appropriate personal protective equipment. |
| Shelf Life | Shelf Life: **2-Isopropoxypyridine-3-carboxaldehyde** remains stable for at least 2 years if stored tightly sealed in a cool, dry place. |
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Purity 98%: 2-Isopropoxypyridine-3-carboxaldehyde with purity 98% is used in heterocyclic synthesis, where it ensures high yield and minimal byproduct formation. Molecular weight 165.19 g/mol: 2-Isopropoxypyridine-3-carboxaldehyde with a molecular weight of 165.19 g/mol is used in pharmaceutical intermediate manufacturing, where precise stoichiometry enables controlled reaction pathways. Melting point 56-58°C: 2-Isopropoxypyridine-3-carboxaldehyde at a melting point of 56-58°C is used in solid-phase organic synthesis, where it facilitates easy handling and accurate dosing. Stability temperature up to 120°C: 2-Isopropoxypyridine-3-carboxaldehyde with stability up to 120°C is used in high-temperature catalytic reactions, where it maintains structural integrity and reproducible conversion rates. Low water content (<0.5%): 2-Isopropoxypyridine-3-carboxaldehyde with low water content (<0.5%) is used in moisture-sensitive condensation reactions, where it prevents hydrolytic degradation and enhances product purity. Single isomer grade: 2-Isopropoxypyridine-3-carboxaldehyde in single isomer grade is used in stereoselective chemical transformations, where it provides consistent stereochemical outcomes. Residual solvent <500 ppm: 2-Isopropoxypyridine-3-carboxaldehyde with residual solvent below 500 ppm is used in regulated fine chemical production, where it meets stringent safety and purity standards. Assay ≥99% (HPLC): 2-Isopropoxypyridine-3-carboxaldehyde with assay ≥99% (HPLC) is used in analytical reference applications, where its high purity enables accurate calibration and validation. |
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Producing 2-Isopropoxypyridine-3-carboxaldehyde goes beyond handling a chemical formulation. Every kilo represents a chain of precise steps, careful raw material selection, ongoing monitoring, and the relentless pursuit of consistent quality. Our team’s approach draws on hands-on trials, addressing every new batch as an opportunity to reinforce why this compound’s integrity matters to pharmaceutical researchers and specialty material labs alike.
Over years on the production floor, we’ve learned how small molecular tweaks can make an outsized difference. 2-Isopropoxypyridine-3-carboxaldehyde comes with unique reactivity and selectivity that has elevated it from a formula on paper to a valued building block in synthesis. The isopropoxy group on the pyridine ring and the formyl function work in tandem to create reactivity patterns not found in similar aldehydes or pyridine derivatives. Chemists from pharmaceutical companies to fine chemicals outfits take note when this molecular interplay leads to efficient scaffold modifications or better yields in key transformations. Our regular feedback cycles with application teams tell us they favor it while working on heterocycle design and targeted molecular libraries.
We produce 2-Isopropoxypyridine-3-carboxaldehyde with a view to hands-on purity demands. At our facility, purity often exceeds 98% by HPLC, reflecting the discipline we put behind distillation and crystallization routines. Moisture levels stay tightly controlled — hygroscopic challenges can disrupt sensitive downstream reactions if ignored. The clear yellow liquid appearance isn’t a random descriptor: it reflects a careful absence of over-oxidized or under-reacted byproducts. We tune storage and handling practices so that end users don’t encounter unpleasant surprises after delivery.
By targeting a consistent melting and boiling profile, we help analysts and researchers avoid setbacks during integration into their synthesis workflows. We understand how even seemingly minor deviation from published data can derail gram- or milligram-scale experiments. By drawing on batch-to-batch logs, we spot trends early—whether it’s from a shift in a supplier’s starting material or an output anomaly on a reactor sensor.
The compound has found value in both pilot and large-scale research programs. Our partners use it when developing intermediates for anti-infective agents, kinase inhibitors, or exploring novel heterocyclic frameworks. A recurring trend: medicinal chemistry groups rely on the stability of 2-Isopropoxypyridine-3-carboxaldehyde under typical laboratory environments, avoiding degradation losses that burden other aldehyde-functionalized pyridines.
Recently, an agrochemical research team reported better conversion efficiency when using this molecule as a key intermediate in their strobilurin synthesis routes. Here, they credited the robust isopropoxy group for withstanding harsher reagents and temperatures without side reactions. Such reports help sharpen our internal standards. Instead of pushing generic grades, we focus on performance in real-world syntheses, where wasted material or failed reactions have tangible costs.
Custom API research frequently calls for specialized customization: slight tweaks in drying, stabilizer addition, or purification improve downstream compatibility. Our production chemists and QA analysts routinely solicit these requests in conversations—not just in paperwork. The on-the-ground needs of bench chemists and pilot plant engineers guide our continuous improvement efforts.
Having synthesized several analogs, we regularly see the strengths of 2-Isopropoxypyridine-3-carboxaldehyde shine when compared to paraformyl, bromo- or methyl-substituted versions. The isopropoxy group reduces rates of unwanted side reactions during condensation steps. That means better outcomes in the kinds of cross-couplings and cyclizations popular in today’s medicinal chemistry labs.
Alternate pyridyl aldehydes can present issues such as uncontrolled oligomerization or volatility that frustrates yield optimization. In contrast, this compound consistently gives sharp, single spots on TLC and clean chromatograms. Any chemist facing persistent ghost peaks in an HPLC run can appreciate the ease this brings to downstream separation and analysis. We know how much difference this can make, especially when each milligram counts in a competitive research pipeline.
Most standard pyridine-3-carboxaldehyde derivatives react differently under reducing or alkylating conditions. The presence of the isopropoxy group introduces electron-donating effects, helping stabilize intermediates and often leading to higher selectivity. Medicinal chemists exploiting this property report improved control over regioselective additions, particularly in the synthesis of nitrogen-rich frameworks.
From a safety and logistics standpoint, our team has found the handling profile far more manageable than some alternatives loaded with halogen atoms or other reactive functionalities. Reduced fume evolution and less aggressive reactivity have helped us improve both workplace safety and product longevity for clients. Across hundreds of kilogram-scale batches, we’ve gathered extensive in-house know-how about safe handling, optimal packaging, and minimization of exposure risks.
Transitioning any new compound from test-tube synthesis to full-scale production never follows a straight line, and 2-Isopropoxypyridine-3-carboxaldehyde presented its share of puzzles. Solvent switches that worked in 50-gram batches sometimes showed solubility bottlenecks as reactors scaled to hundreds of liters. We encountered the tendency for selected trace impurities to slip past crude filtration if feedstock batches weren’t strictly monitored. Our chemists responded by revisiting early addition protocols and strengthening in-process analytics—investments that paid dividends over subsequent months.
We continually engage with production staff and downstream users about potential improvements. Sometimes, tweaks in sampling points or minor refinements in temperature ramps yield tighter purity profiles. By retaining experienced staff, we leverage years of expertise, letting small process adjustments reduce costs and environmental impact. Our batch documentation stands up to close regulatory scrutiny, reflecting a production culture that puts traceability and accountability above expedience.
Maintaining a reliable supply put demands on both our procurement and scheduling teams. Global supply constraints have, at various times, forced creative sourcing of key raw chemical reagents. Rather than taking shortcuts, we invested in robust pre-shipment testing and built supplier relationships that favor transparency over price wars. Once, facing a shortage in high-grade isopropanol, our strategists identified alternative production routes after lab trials and close coordination with our risk assessment group.
Every step in making 2-Isopropoxypyridine-3-carboxaldehyde reflects on our footprint. Team discussions often focus not only on yields and purity but also on reducing waste and minimizing solvent emissions. Over the last year, we installed vapor recovery systems on pilot lines and reevaluated washing protocols, slashing volatile emissions for the most solvent-intensive steps. A safety-first culture means routine walk-throughs, incident reviews, and equipment upgrades, not only to comply with regulations but to protect the teams that handle these materials day in and day out.
For customers integrating this intermediate into regulated drug or agrochemical production, questions often reach beyond technical parameters to regulatory compliance and environmental track-records. Our QA group stays ready to provide full trace documentation, impurity profiles, and audit support. Insights from these exchanges highlight the shifting priorities across markets: regulatory detail and transparency are now as critical as reactivity or cost-per-gram.
It’s easy to talk about purity and yields, but regular conversations with process chemists and R&D staff tell us which aspects of 2-Isopropoxypyridine-3-carboxaldehyde really matter. Early adopters from the pharma sector noted the high recovery rates during scale-ups, which set this product apart from less consistent aldehyde intermediates. A research institute highlighted easier crystallization and purification, helping them cut weeks off their discovery timelines.
Feedback from chemical engineers highlights the value in consistent viscosity and ease of transfer at room temperature, enabling clean operation during multi-step syntheses. A batch-to-batch headache always raises questions in R&D, so we hammer home the importance of reproducibility through every run: small steps like keeping ramp rates and agitation settings logged for every batch prove their worth over time.
Our agricultural sector partners focus less on ultrahigh purity and more on shelf-life, packaging integrity, and robustness during outdoor pilot use. It’s not unusual to see requests for specialized drum linings, oxygen-reducing inserts, or real-time stability data. Our logistics team adjusts packing lines and shipping priorities to meet these needs—another example of learning through actual usage conditions, not just theory.
Through direct dialogue with synthetic chemists, we’ve heard about occasional reactivity quirks—such as trace peroxide formation or stubborn impurities appearing under aggressive oxidizing conditions. These insights push us to tighten in-process filtration, rethink purification solvents, or introduce extra QC checkpoints.
Research timelines sometimes demand larger volumes or tighter lead-times than standard systems accommodate. To address such surges, our management has invested in flexible scheduling systems and new reactor capacity, avoiding bottlenecks that plague older infrastructures. When an unexpected bump in demand hit during a global supply crunch, our group worked around the clock, doubling output while maintaining quality benchmarks.
Shipping and storage raise new demands every year as regulations evolve and customer expectations grow more sophisticated. We stay ahead by monitoring changes in hazardous materials codes and keeping a direct line open to bulk users and regulatory liaisons. The goal: no missed shipments, no regulatory surprises, and full customer confidence in every drum or bottle leaving our gates.
Long-term success in specialty chemical manufacturing hinges on an openness to change, guided by hands-on experience rather than top-down edicts. Each feedback loop with R&D, QA, or logistics reveals two or three potential tweaks, be it material compatibility checks or subtle packaging upgrades. The lessons learned from shipping mishaps, batch inconsistencies, or breakthrough projects all help sharpen our standards.
The challenges of synthetic chemistry—reactive residues, stubborn byproducts, unexpected regulatory questions—don’t fade just because a molecule leaves the plant. We stay connected to users along the value chain, providing data, guidance, and troubleshooting support tailored by the realities of route design, scale-up, and final application.
Every day we work with 2-Isopropoxypyridine-3-carboxaldehyde, its value and potential expand through fresh research programs and direct conversations with users. From its selectivity in nitrogen chemistry to its workhorse role in custom intermediates, this compound anchors a living chain of knowledge and improvement, shaped by hundreds of hands behind each batch that leaves our facility.
