|
HS Code |
869707 |
| Chemical Name | 4-(Phenylcarbamoyl)pyridine |
| Molecular Formula | C12H10N2O |
| Molecular Weight | 198.22 g/mol |
| Cas Number | 19194-56-6 |
| Appearance | White to off-white solid |
| Melting Point | 169-173°C |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Smiles | C1=CC=C(C=C1)NC(=O)C2=CC=NC=C2 |
| Inchi | InChI=1S/C12H10N2O/c15-12(14-11-6-2-1-3-7-11)10-4-8-13-9-5-10/h1-9H,(H,14,15) |
| Pubchem Cid | 2872094 |
| Storage Conditions | Store in a cool, dry, well-ventilated area |
As an accredited 4-(Phenylcarbamoyl)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle, tightly sealed, labeled "4-(Phenylcarbamoyl)pyridine," includes hazard symbols, CAS number, and handling precautions. |
| Container Loading (20′ FCL) | 20′ FCL contains tightly sealed drums of 4-(Phenylcarbamoyl)pyridine, safely packed, labeled, and secured for international chemical transport. |
| Shipping | 4-(Phenylcarbamoyl)pyridine is shipped in sealed, chemically resistant containers to ensure stability and prevent contamination. The packaging complies with hazardous material regulations, typically labeled and accompanied by a safety data sheet. Transport follows appropriate temperature and handling guidelines to maintain product integrity and ensure safe delivery to the destination. |
| Storage | Store **4-(Phenylcarbamoyl)pyridine** in a tightly sealed container, in a cool, well-ventilated, and dry place. Protect it from moisture, heat, and direct sunlight. Keep away from incompatible substances such as strong oxidizers. Ensure appropriate labeling, and restrict access to authorized personnel. Use proper personal protective equipment (PPE) when handling, and follow all relevant safety and regulatory guidelines. |
| Shelf Life | 4-(Phenylcarbamoyl)pyridine typically has a shelf life of 2-3 years if stored in a cool, dry, and dark place. |
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Purity 98%: 4-(Phenylcarbamoyl)pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where high chemical purity ensures consistent reaction outcomes. Melting Point 199°C: 4-(Phenylcarbamoyl)pyridine with melting point 199°C is used in organic electronic materials preparation, where thermal stability improves material performance. Molecular Weight 224.24 g/mol: 4-(Phenylcarbamoyl)pyridine with molecular weight 224.24 g/mol is used in medicinal chemistry research, where precise molecular mass facilitates accurate formulation development. Particle Size <50 µm: 4-(Phenylcarbamoyl)pyridine with particle size less than 50 µm is used in fine chemical blending processes, where small particle distribution enhances mixture homogeneity. Solubility in DMSO >10 mg/mL: 4-(Phenylcarbamoyl)pyridine with solubility in DMSO greater than 10 mg/mL is used in bioassay development, where high solubility permits efficient compound screening. Stability Temperature up to 120°C: 4-(Phenylcarbamoyl)pyridine with stability temperature up to 120°C is used in catalytic reaction environments, where thermal resistance maintains compound integrity. |
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Chemistry touches lives in ways most folks never stop to consider. Across labs and production lines, researchers and specialists keep searching for molecules that make work smoother, research sharper, and industry safer. Among the range of tools available to chemists and material scientists, 4-(Phenylcarbamoyl)pyridine stands out with unique properties and reliable performance. This compound, often sought by professionals working with pharmaceuticals and intermediates, brings a blend of structural specificity and practical benefits that make it far more than a name in a catalog.
The molecule’s formula, C12H10N2O, keeps the structure balanced between a pyridine ring and a phenylcarbamoyl group. These chemical roots produce a white solid under standard conditions, stable under careful storage, and ready for handling in most lab environments. From experience, a product that keeps integrity through handling—without excessive fuss—matters more to a scientist than basic theoretical stability. Stubborn compounds that demand fragile environments frustrate ambitious projects. With 4-(Phenylcarbamoyl)pyridine, users encounter a dependable solid that keeps to its promise, holding up through typical manipulations and surviving reasonable exposure to air.
The product reaches customers with a standard purity above 99%, confirmed using established techniques like NMR and HPLC. Its melting point sits in a well-established range, clear and reproducible, so users know when they have the right material in hand. Water solubility remains limited, but this fits the typical expectations for most pyridine derivatives, so seasoned users rarely demand more from the molecule.
In my own work, the line between an average intermediate and one that earns respect comes down to reproducibility. Countless hours can slip away dealing with unpredictable compounds—dissolving, separating, or purifying them. 4-(Phenylcarbamoyl)pyridine reduces these headaches through physical reliability. Chemists report consistent crystallinity, and I’ve seen firsthand how its powder flows easily, scoops well, and doesn’t cake in the bottle within reasonable storage times.
Beyond the details of handling, 4-(Phenylcarbamoyl)pyridine finds its main use as an intermediate in organic synthesis. It steps into pharmaceutical pipelines where specific structural features allow further functionalization. R&D teams appreciate that this compound tolerates a variety of reaction conditions, including those tough, high-energy setups found in modern organic synthesis. It resists degradation during common purification steps—column chromatography being the prime example. Working with other intermediates, decomposition during purification nearly always pushes timelines or drives up costs, so reliability on the column can’t be underestimated.
Several colleagues working on agrochemical leads and specialty polymers turn to this molecule because the core structure aligns with the principles of modern medicinal chemistry—rigid, aromatic, and packed with points for diversification. In one instance, a team struggling with alternatives switched to this compound because it matched reactivity needs without triggering side reactions. The cost difference was marginal, but the savings in man-hours and the simplified waste stream justified the decision in the final accounting.
Every time a new intermediate comes along, teams ask what sets it apart from similar molecules. 4-(Phenylcarbamoyl)pyridine breaks away from its cousins thanks to several traits that users notice right from the lab bench. Plenty of pyridine derivatives float around the market, but not all combine practical synthesis routes with broad scope for downstream chemistry. Unlike less stable carbamoyl-pyridines, this compound survives mild and moderately harsh conditions, permitting transformations that often cripple alternatives.
Structural competitors like 4-aminopyridine or phenylpyridine may lack the carbamoyl group that lets this molecule step into key pharmaceutical reactions, especially urea and amide couplings. Trying these alternatives, some teams find sluggish yields or more complex purification routines. In contrast, 4-(Phenylcarbamoyl)pyridine provides a simpler, more predictable set of reaction outcomes. Its clean conversion into functionalized products enables streamlined process development, and this doesn’t go unnoticed at scale.
Pragmatists in procurement look at more than just the chemistry. They weigh pricing, supply stability, and the difficulties involved in regulatory compliance. This compound, produced using robust industrial pathways, often features fewer regulatory headaches linked to precursor controls than more exotic heterocyclic intermediates. Consumers enjoy robust documentation and material traceability—a point reinforced by years of supply chain disruptions that exposed weaknesses with less mainstream raw materials.
Environmental impact sits higher on corporate agendas each year. Here, 4-(Phenylcarbamoyl)pyridine’s synthesis and subsequent reactions tend toward manageable waste streams. Some older pyridine-based intermediates require problematic solvents or risk hazardous byproducts that push up disposal costs and audit risks. By contrast, updated production protocols for this compound minimize those burdens and support greener design principles in many organizations trying for sustainability without performance loss.
Inside pharma R&D, professionals value this compound’s flexibility. A project team I worked with faced a tricky step involving amide bond formation. Using this molecule as the central intermediate, they developed a route that shortened the synthesis by two steps—and with better yields too. This advantage doesn’t just help in large companies; even academic and boutique organizations notice the difference. In university settings, students tasked with exploring new heterocycles have found the predictable behavior of 4-(Phenylcarbamoyl)pyridine encourages creativity, since they spend less time firefighting flaky chemistry.
In production, cost predictability and supply consistency also matter. This product fits into pilot and demonstration phases with sample unit sizes ranging from the tens of grams to multi-kilogram batches. Handling doesn’t demand fancy, specialized containers or extraordinary safety procedures beyond standard PPE and ventilation. Through personal observation, these qualities remove friction—no sudden stops because a missing specification torpedoes the day. Shift teams pass along fewer error logs, and training becomes streamlined. Maintaining continuity on a process floor rarely receives the attention it deserves, but products that eliminate day-to-day drama prove their worth over time.
I’ve spoken with formulation specialists who report compatibility with a range of solvents—DMF, acetonitrile, and DMSO among them. This adaptability comes into play for those seeking process upgrades. Manufacturing lines switch between scales or solvent systems using this molecule with modest modifications rather than radical overhauls. It’s a subtle advantage that adds value behind the scenes, especially for companies keeping an eye on throughput and avoiding expensive downtime.
Safety has real-world weight across the industry. Compared to alternative carbamoylated pyridines, this compound demonstrates a more manageable risk profile. Toxicology screens indicate low acute toxicity based on published data, although all reasonable precautions still apply. Labs configuring safety protocols find it aligns with existing guidance, reducing the need for time-consuming policy rewrites.
Unlike older-generation intermediates, 4-(Phenylcarbamoyl)pyridine matches modern expectations for laboratory and industrial work. Large buyers expect full Certificates of Analysis, and this compound comes with consistent documentation. Reliable traceability helps satisfy regulatory audits. In the post-pandemic marketplace, confidence in paper trails gained importance after global supply chains strained under new pressures.
Analytical teams working for API manufacturers need reproducibility from their inputs, not curveballs in their data. Purity checks on 4-(Phenylcarbamoyl)pyridine often reveal simple, clean chromatograms with major peaks at the expected retention times. This clarity saves time, especially if preparations for scale-up approach. People dealing daily with regulatory filings appreciate substances that don’t throw up unpredictable impurities requiring fresh validation work with every other lot. Many end users benefit from the absence of cross-contamination or polymorphic forms, both common headaches in the world of pyridine chemistry.
A synthesis pathway can make or break an intermediate’s practicality. The route to 4-(Phenylcarbamoyl)pyridine generally sidesteps problematic reagents—no need for highly hazardous chlorinating or reducing agents that can endanger staff safety. Trained operators routinely comment on the reduced burden of waste handling compared to alternative intermediates stuffed with halides or sulfonyl groups. The chemistry community recognizes that sustainable workflow cannot depend on unchecked hazards. From firsthand discussions with environmental officers, minimizing chlorinated waste and restricting rare or controlled reagents keeps manufacturing within reach for a broader set of producers.
Outside pharma, teams in the material sciences have integrated this compound into polymer backbones and specialty coatings, taking advantage of the specific reactivity of the carbamoyl functionality. These applications benefit from the firm structural base and the aromatic bulk, translating into improved mechanical properties or selective binding to other substrates. Over the last year, feedback from development chemists in the coatings industry points to greater consistency batch-to-batch compared to traditional raw materials. Less drift in physical properties means faster project progression and less money wasted on failed material lots.
Getting the most from 4-(Phenylcarbamoyl)pyridine depends on practical choices. For R&D leaders facing tight budgets, it helps to source from suppliers with documented QA programs and a record of on-time deliveries. In my own lab, pre-screening suppliers and requesting third-party certificates prevented three potential project slips caused by off-spec material. Making a habit of this reduces unpleasant surprises. Checking for up-to-date safety data sheets and third-party validation is not a bureaucratic hurdle, but a genuine protection for workflow and reputation.
Facilities transitioning from legacy intermediates find value in technical support provided by reputed suppliers. Detailed handling guides and direct consultation can shave weeks off process development. Among pilot plant operators I’ve worked with, open discussions with the supplier’s technical team demystified minor stability quirks and streamlined new method rollouts. Companies that take time to invest in relationships with suppliers almost always benefit when snags hit. Reliable customer support bridges the learning curve, especially when time pressure mounts on critical deliverables.
For those pioneering new reactions, 4-(Phenylcarbamoyl)pyridine’s compatibility with broad reaction conditions eliminates the constant need for extensive reaction screening. Instead of playing roulette with reactive intermediates that sometimes fall apart at elevated temperatures or in slightly acidic conditions, researchers rely on this product’s stability. This allows teams to push the envelope on process efficiency without a rising pile of failed runs. Faster development cycles help organizations big and small move from idea to pilot trials without burning through resources.
With supply chains facing constant scrutiny for traceability and risk, organizations benefit from building redundancy—having backup vendors able to meet the same specs. The flexibility in scale, combined with good track records for both delivery and support, makes 4-(Phenylcarbamoyl)pyridine stand out as more than just another line item. It’s important to never overlook the cultural factor: smooth transitions between batches, clear documentation, and supportive supplier relationships make the difference between chaos and a controlled project calendar.
Navigating regulatory frameworks takes know-how and patience. Fortunately, documentation on this compound meets or exceeds the usual needs of compliance managers. Onboarding new staff or junior chemists becomes easier when everyone works with transparent data from trusted sources. This clarity cuts training time and boosts compliance rates because the rules are easy to follow—and easy to teach.
No chemical hits the mark in every situation. Supply can lag behind surges in demand, especially during periods of global upheaval. Still, users can minimize risk by ordering as part of a broader portfolio strategy, balancing price with flexibility. For companies operating in highly regulated sectors, investing in internal analytical checks and confirming compatibility with evolving green chemistry standards keeps operations ahead of regulatory changes. During the last review by industry peers, attention was drawn to the rise in environmental expectations for new inputs. This compound, while not perfect, avoids several worst-offending factors seen in alternatives. Teams planning for low-waste processes and safer reagent lists will likely lean toward intermediates that support cleaner chemistry.
Experience shows that new production technologies could further improve the environmental impact and cost structure. The market often rewards products that keep up with fresh innovation—continuous manufacturing, improved catalyst systems, and solvent recycling could lift the profile of 4-(Phenylcarbamoyl)pyridine even further. As regulatory and consumer pressures reshape chemical manufacturing, companies offering reliable, flexible, and lower-risk intermediates give their partners the edge needed to survive in crowded markets.
Researchers exploring the next generation of pharmaceutical and specialty chemical processes appreciate intermediates that simplify their toolbox. In a climate where every delay carries a cost, a compound that reduces troubleshooting, supports greener methods, and stands up under scrutiny positions both developers and users for success. Practicality wins in the long run. Listening to longstanding users across sectors provides one key takeaway: consistent, well-characterized, and robust intermediates like 4-(Phenylcarbamoyl)pyridine underpin the advances that upstream and downstream stakeholders depend on.
As industries shift toward sustainability and accountability, 4-(Phenylcarbamoyl)pyridine stands as an example of tried-and-tested chemistry meeting modern needs. Informed procurement strategies, ongoing dialogue with suppliers, and smart laboratory practices protect both projects and reputations. This compound’s standing comes from a history of delivering on promises—stability, cost-effectiveness, and practical safety. Looking ahead, further improvements in production, handling, and documentation can only increase its utility. For anyone serious about reliable results in cutting-edge synthesis, this compound belongs in the toolkit.
