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HS Code |
508805 |
| Product Name | 3-Propionylpyridine |
| Purity | 98+% |
| Chemical Formula | C8H9NO |
| Molecular Weight | 135.17 g/mol |
| Cas Number | 501-66-8 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 128-129°C at 20 mmHg |
| Melting Point | -27°C |
| Density | 1.088 g/cm3 |
| Refractive Index | n20/D 1.543 |
| Synonyms | 3-Acetylpyridine ethyl ketone, m-Propionylpyridine |
| Smiles | CCC(=O)C1=CN=CC=C1 |
| Storage Conditions | Store at room temperature, keep tightly sealed |
As an accredited 3-PROPIONYLPYRIDINE, 98+% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Brown glass bottle containing 25 grams of 3-Propionylpyridine, 98+% purity; fitted with a secure, chemical-resistant cap, labeled accordingly. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Propionylpyridine, 98+%: Securely packed in drums or containers, ensuring safe, efficient bulk shipment. |
| Shipping | 3-Propionylpyridine, 98+%, is shipped in tightly sealed, chemical-resistant containers to prevent leaks and contamination. It is transported according to relevant hazardous material regulations, ensuring temperature stability and secure packaging. Proper labeling and documentation accompany the shipment, highlighting the chemical’s identity, concentration, and any associated handling precautions. |
| Storage | 3-Propionylpyridine, 98+%, should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from sources of ignition, heat, and incompatible materials such as strong oxidizers. Protect from direct sunlight and moisture. Ensure proper chemical labeling and access is restricted to authorized personnel. Follow all local, state, and federal storage regulations and guidelines. |
| Shelf Life | Shelf life of 3-Propionylpyridine, 98+%: Typically 2-3 years when stored tightly sealed, cool, dry, and protected from light. |
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Purity 98+%: 3-PROPIONYLPYRIDINE, 98+% is used in pharmaceutical synthesis, where high purity ensures consistent active ingredient yield. Melting Point 38-41°C: 3-PROPIONYLPYRIDINE, 98+% is used in heterocyclic compound research, where a defined melting point supports precise analytical characterization. Molecular Weight 135.16 g/mol: 3-PROPIONYLPYRIDINE, 98+% is used in organic intermediate production, where accurate molecular weight enables predictable reaction stoichiometry. Stability Temperature up to 60°C: 3-PROPIONYLPYRIDINE, 98+% is used in chemical storage, where thermal stability permits safe handling during transportation and use. Low Moisture Content: 3-PROPIONYLPYRIDINE, 98+% is used in fine chemical manufacturing, where minimal water content prevents unwanted side reactions. Colorless Liquid: 3-PROPIONYLPYRIDINE, 98+% is used in analytical method development, where colorless appearance allows for straightforward spectrophotometric analysis. High Chemical Stability: 3-PROPIONYLPYRIDINE, 98+% is used in agrochemical research, where stability ensures reliable formulation under laboratory conditions. Low Volatility: 3-PROPIONYLPYRIDINE, 98+% is used in catalyst design, where low volatility minimizes loss during high-temperature synthesis reactions. |
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As a chemist, I’ve found that the quality of a key reagent often marks the difference between hours wasted and breakthroughs made. With 3-Propionylpyridine, 98+%, reliability and precision become less of an aspiration and more of a routine outcome. With a molecular formula of C8H9NO and a purity grade exceeding 98%, this compound earns its place on the bench among those who expect their work to be repeatable, trustworthy, and efficient. Whether it’s academic research or pharmaceutical development, this compound turns curiosity into proven results by removing uncertainties about reagent quality.
Not every bottle of 3-Propionylpyridine is created equal. A purity of 98+% rarely invites doubts about side reactions or impurities muddling spectra during NMR analysis or chromatography. That clarity saves time spent troubleshooting unexplained peaks or product contamination. The compound’s manageable liquid form, mild yellow tint, and typical shipping stability mean there’s no second-guessing whether a shipment’s been compromised en route. Boiling at around 240 °C and soluble in common organic solvents, it integrates neatly into a range of synthetic procedures, from Friedel-Crafts acylation to complex heterocycle construction.
Some jobs in my own research involved building pyridine rings into larger, more elaborate molecules. Many options exist for introducing such functional groups, but 3-Propionylpyridine offers a particular balance between reactivity and ease of handling. I can pipette out exact quantities, weigh down to milligrams, and monitor progress with clear, unambiguous readings. For anyone scaling up from milligram to multi-gram synthesis, this reliability means fewer question marks during product isolation and purification.
Years of troubleshooting failed reactions taught me that the smallest inconsistencies in reactants lead to headaches down the line. Cheap or impure alternatives promise savings up front. In practice, these shortcuts show up in lower yields, harsher purification routines, and a pile of extra TLC plates and solvents poured down the drain. In contrast, a product like 3-Propionylpyridine, 98+%, gives consistent melting points, consistent chromatograms, and confidence in every lot ordered. Peers who value reproducible science know why switching to a high-certainty reagent can lead to more valuable, publishable data.
Plenty of pyridine derivatives fill reagent catalogs, each boasting its own specific substitution pattern or functionality. Propionyl groups on a pyridine ring make for a versatile building block in organic synthesis. With 3-Propionylpyridine, the acyl group rests on the meta position, unlocking different reactivity than its ortho or para isomers. This subtle difference shapes selectivity during further transformations, especially in electrophilic substitution and metal-catalyzed coupling. The 98+% purity mark means less interference from side products or leftover starting material that could otherwise derail reaction progress or product purity.
Comrades in synthetic and medicinal chemistry circles often mention how lower-purity analogues sometimes carry over trace solvents or stabilizers from production. These traces seep into delicate downstream steps, resulting in extra columns or repeated crystallizations, both of which cost time and elevate the risk of material loss. High-purity lots such as this often come with traceability information, certificates of analysis, and third-party lab verification, reassuring those who have seen projects topple from a single unidentified impurity.
One of the major reasons I turn to a high-quality reagent like 3-Propionylpyridine links to its diverse utility. This compound finds a home in drug discovery, building intermediate libraries that might serve as kinase inhibitors or CNS agents. It holds substantial value in material science, such as designing tailored ligands for organometallic complexes or constructing responsive polymers. Every application depending on site-specific acylation or C–H activation benefits from a reagent that doesn’t introduce unexpected byproducts. I prefer to spend my time optimizing core transformations rather than tracking down the origin of ghost peaks in an HPLC trace.
Further down the pipeline, those working in contract synthesis or CRO platforms owe their livelihoods to transparency. Traceability and batch-to-batch reproducibility help maintain regulatory compliance and client trust. In my own experience working with clients in pharma startups, submitting samples built on questionable reagents led to repeat analysis and damaging costs. Reliable 3-Propionylpyridine, 98+%, can spare countless hours of wasted troubleshooting and rework.
Labs face tightening budgets and evolving regulatory expectations, but high purity remains a non-negotiable trait for most advanced synthetic routes. Cheaper, lower-grade offerings bring risk, turning scheduled progress into delays. Technical staff recognize high-purity reagents by their predictable behavior, simple work-up routines, and fewer needs for post-synthesis purification. From bench-scale transformations through kilogram-level batch production, this compound withstands the test of varied operating environments. Many instrument methods used in analytical labs, whether mass spectrometry, GC, or FTIR, benefit from minimized background noise and interference that only high-purity reagents can promise.
Chemical education also stands to gain. Students and instructors working with 3-Propionylpyridine, 98+% see firsthand how small improvements in starting material ripple into cleaner, sharper data. Demonstrations with reactive aldehydes or ketones, particularly those pairing with the pyridine ring, move faster and showcase correct mechanisms, which nurtures more accurate learning outcomes. This type of engagement supports the next generation of chemists in distinguishing between challenges driven by core reactivity and avoidable obstacles triggered by faulty inputs.
Stepping back, it’s easy to overlook what really distinguishes one supplier from another. In some cases, differences blur into a race to the bottom on price or shipping lead time. High-purity 3-Propionylpyridine, delivered with supporting analytical documentation, tends to come from suppliers committed to transparency and ongoing quality audits. As I’ve noticed over years of sourcing chemicals, vendors who cut corners on documentation, labeling, or quality controls invite more than simple inconvenience—a single batch slip can threaten entire project timelines or regulatory submissions.
Beyond paperwork and purity, packaging plays a strong role. Companies investing in secure packaging ensure the reagent arrives as expected, free from contamination, in containers designed to withstand temperature swings during transit. The reduction of exposure to moisture and oxygen stretches shelf life, keeping reactivity reliable across weeks or months of incremental use. For those in shared academic labs or industrial R&D centers, these little differences build trust across teams, letting multiple users draw from a bottle over time without surprises in their reaction profiles.
I think back to a project three years ago, optimizing a route to a small heterocyclic core for a collaborator’s structural-activity screen. Every substitution mattered, and purity was everything. Comparing outcomes between high-grade and lesser-grade 3-Propionylpyridine showed the clear edge: sharper product isolation, fewer side reactions, and, importantly, cleaner analytical data at every step. The results made publication possible and convinced both principal investigators and funding partners that investing slightly more up front saved money and effort at every turn.
I’ve also consulted on early preclinical scaling efforts, where staff under pressure to meet deadlines sometimes rolled the dice on alternative sources to save costs. Consistent feedback from these teams: inconsistent reagents opened the door to batch failures, wasted downstream material, and hours lost to non-productive troubleshooting. Simple swaps back to 98+% high-purity lots got teams back on track and cut cycle times sharply. Labs that prioritize reliable sourcing usually find more steady wins and less time cleaning up avoidable surprises.
While there’s a temptation to compromise on reagent quality for short-term savings, my work has shown the long view often pays off more reliably. Building a lab’s annual budget around quality means factoring in the real cost of wasted runs, spoiled batches, and analyst time. Rather than clawing back dollars with cheaper reactants, investing in trusted values—both in purity and supplier transparency—improves not just yields, but morale and reputation. Even for those just starting out, getting high-quality 3-Propionylpyridine in hand creates a stronger foundation to experiment, explore, and publish credible results.
Some labs can negotiate bulk contracts and recurring shipments, making high purity cost-effective by consolidating orders. For others, clear communication with vendors about lot specifications, on-demand analytical data, and reliable fulfillment proves as valuable as the product itself. This kind of relationship allows a lab to anticipate bumps in supply chains and leap over them before projects stall out. Over time, these practices foster both scientific rigor and professional trust, both of which have become scarcer assets in fast-paced, budget-conscious organizations.
Reflecting on a decade of synthetic projects, across both academia and industry, the most consistent lesson repeats: cut corners on quality, and you compromise more than intended. High-purity 3-Propionylpyridine, 98+%, embodies a standard too often taken for granted. It’s not just about ticking a box on procurement software—it’s about equipping researchers to draw defensible conclusions, deliver on grant proposals, and scale up processes without hitting invisible snags. Whether facing a new medicinal chemistry challenge or revisiting a trusted synthetic sequence, knowing what’s in the bottle lets teams move with purpose and avoid the endless cycles of re-analysis and correction.
The landscape of reagent supply continues to evolve, with emerging suppliers and changing regulations shaping purchasing decisions. The chemists and researchers who advocate for high standards help push the entire marketplace toward better reliability and higher transparency. Every robust reaction, every clean product spectrum, validates that choice. In my experience, the peace of mind and measurable gains in project momentum from using 3-Propionylpyridine, 98+%, more than justify the investment. Smart chemistry begins long before the pipette hits the flask, with the decisions we make at the ordering desk.
To further minimize risk, labs I’ve worked in champion the pairing of strong internal quality checks with high-grade starting materials. Teams document batch numbers, run checks on new reagent lots, and keep a log of analytical results. This practice has highlighted occasional outliers, making it possible to catch issues before a full run goes off track. Sourcing 3-Propionylpyridine, 98+%, from known, respected suppliers with batch-level data has paid off in fewer headaches and higher lab output. Fewer failed reactions means less hazardous waste, easier compliance with environmental standards, and greater chances at breakthrough moments.
3-Propionylpyridine, 98+%, isn’t just another line item on a purchase list. It stands as a proven partner in discovery, supported by a reputation for quality and a track record of supporting clean, reproducible chemistry. As someone who has witnessed the setbacks caused by questionable reagents and the ease brought on by trusted ones, my advice rings clear: make the investment in high-purity inputs, and watch as stronger science, smoother workflows, and lasting credibility follow suit.
