|
HS Code |
938811 |
| Cas Name | L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1) |
| Other Ca Index Names | Pyridine, 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]-, compd. with N-acetyl-L-phenylalanine (1:1) |
| Molecular Formula | C18H24ClN2O • C11H13NO3 |
| Molar Ratio | 1:1 |
| Molecular Weight | Exact values depend on specific salt form; sum is approximately 547.02 g/mol |
| Physical Appearance | Solid (exact color/form may vary) |
| Solubility | Varies by solvent; likely soluble in polar organic solvents |
| Chemical Structure Type | Organic salt/compound |
| Functional Groups | Pyridine, Piperidine, Chlorophenyl, Acetyl, Amino acid (phenylalanine) derivative |
| Chirality | Contains stereogenic centers (S-configuration) |
| Alternate Names | No widely established trade names; may be referenced by component names |
As an accredited L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1) OTHER CA INDEX NAMES: Pyridine, 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]-, compd. with N-acetyl-L-phenylalanine (1:1) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, sealed HDPE bottle containing 25 grams of fine powder, labeled with chemical name, hazard symbols, lot number, and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely loads bulk cartons or drums of the compound, maximizing capacity and ensuring safe international chemical transport. |
| Shipping | **Shipping Description:** L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1) should be shipped in tightly sealed containers, protected from moisture and light, and maintained at ambient temperature unless otherwise specified. Handle as a non-hazardous chemical unless otherwise classified. Ensure compliance with all local and international chemical transport regulations. |
| Storage | Store **L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1)** in a tightly closed container, protected from light and moisture. Keep at 2–8°C (refrigerated) in a well-ventilated, cool, dry area. Avoid sources of ignition and incompatible substances. Ensure appropriate labeling and limit exposure to air. Handle under an inert atmosphere if stability data recommends. |
| Shelf Life | Shelf life: Store in a cool, dry place; typically stable for 2–3 years if kept in tightly sealed containers, away from light. |
Competitive L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1) OTHER CA INDEX NAMES: Pyridine, 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]-, compd. with N-acetyl-L-phenylalanine (1:1) prices that fit your budget—flexible terms and customized quotes for every order.
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In the world of specialty chemical manufacturing, names can get long and technical, but beneath every one of those mouthfuls sits years of research, investment in equipment, labor in the plant, and a commitment to reliable output. L-Phenylalanine, N-acetyl-, compd. with 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine (1:1) may not roll off the tongue, yet the chemistry behind it makes a visible difference in targeted pharmaceutical and biotechnological processes. We see the impact of these substances on a global scale, so accuracy in discussion always matters. For someone new to this class of compounds, let’s unpack why this one earns its place on laboratory benches and production lines around the world.
This compound stands out for a reason: it brings together two sophisticated building blocks—an acetyl-protected amino acid (N-acetyl-L-phenylalanine) and a functionalized pyridine carrying both a (S)-(4-chlorophenyl) and 4-piperidinyloxy moiety. Each component, designed through careful selection, opens the door to precise targeting and controlled reactivity in both drug discovery and complex organic synthesis. Creating a consistent product with a 1:1 stoichiometry takes genuine process control during manufacturing. From our shop floors, that means strict monitoring of pH, solvent purity, and temperature curves—a slip anywhere in the process impacts yield or purity.
Machines hum and software helps, but it takes trained judgment from people to avoid problems and stay on-spec. Technicians in our faciltiy use direct feedback from in-line analytics, reaching beyond standard operating procedures when necessary. Chemical operators spot changes in viscosity or color tone, experience tells them where UIP, seed bed, or crystallization rate needs a hands-on steer. From weighing to final filtration, this approach makes a difference—customers downstream see fewer impurities and a compound that fits protocols for formulation and testing.
In daily work, numbers like melting point, solubility in various solvents, optical rotation, and NMR spectra serve as our checkpoints, not marketing lines. Typically, purity on these compounds reaches above 98% by HPLC, though we often push for higher, especially once customer feedback loops begin. Physical stability during storage draws as much attention as chemical purity. Moisture content levels, residual solvent traces, and particulate control run center-stage during post-processing and packaging. Chemical composition alone never tells the whole story; lot-to-lot reproducibility depends on these details.
The unique make-up of this compound shapes real-world performance. The N-acetyl-L-phenylalanine backbone gives chirality, critical for how substances interact with biological receptors. By linking it specifically with the 2-[(S)-(4-chlorophenyl)(4-piperidinyloxy)methyl]pyridine group, the resulting material offers increased binding selectivity in target applications—chemists report significant gains in activity or uptake, compared to simpler, unmodified amino acid conjugates. This isn’t just theoretical; our own collaboration with R&D partners has returned tangible results. Where standard N-acetyl-L-phenylalanine may dissolve rapidly or degrade in acidic or alkaline solutions, this salt form brings new resistance and kinetic resilience, especially under the rugged demands of industrial processing.
Those in formulation labs know the difference between a research-grade bottle and a steady, kilogram-scale supply. Our teams see the tension between lab-scale curiosity and production-scale reliability every day. As this compound forms a part of intermediate or active molecule pipelines, ease of handling and consistent reactivity save time. Many synthesis steps involve batchwise conversions prone to side reactions—better control with our product often means greater final yield, reduced waste, and fewer purifications downstream. Here, a well-made compound translates into less night-shift troubleshooting and lower long-run costs.
Lab staff appreciate powders that don’t cake or clump, a factor shaped by drying procedures and proprietary anti-static techniques during packaging. Moisture-sensitive organics like this compound return better results if they arrive in tightly sealed containers, flushed with inert gas, and labelled by both weight and batch input. Our customers routinely pass along comments about how ease of weighing and solution behavior add to efficiency in both manual and automated environments. Whether poured into bench-top reactors or loaded into flow systems, a high-quality batch reduces downtime and troubleshooting.
Many labs still rely on basic N-acyl amino acids, facing frustration when these simpler compounds fail specific bioactivity screens or degrade unpredictably. We’ve seen colleagues lose days to purification bottlenecks, stemming from poor compatibility between reagents. Using the pyridine complex offers solutions—side-chain functionality enables new routes to hybrid molecules and targeted delivery vehicles. Simpler salts might underperform in terms of solubility or lack stability against light or oxygen; our experience—and third-party validation—show this compound resists these common breakdown pathways. For development teams seeking reliable assay data, these differences save significant resources.
Our identity as the actual chemical producer makes a difference in every transaction. From raw material sourcing to final release, full control over upstream and downstream processes helps secure predictable timelines and honest traceability. Technical teams respond directly to customer queries, not through third-party brokers, which means problems get solved in real time. On multiple occasions, we’ve been able to tweak particle size distribution, optimize drying to reduce residual solvents, or accommodate regulatory requests with tailored documentation. This level of collaboration only works if the manufacturer holds true operational knowledge and investment, not just a warehouse link in the chain.
Chemical manufacturing comes with duty. Our teams work under modern emission controls and water reuse protocols—measures that don’t just tick compliance boxes but actually cut waste in real terms. For example, our solvent recovery units reduce fresh consumption by more than 30%, a figure that came through years of process engineering and operator involvement. Waste management teams sort effluents at point of origin, upstream of bulk treatment, using simple technologies that everyone on site understands and trusts. This avoids surprises and secures operating permits from both local and national authorities. We believe customers expect not just purity data, but assurance that each step respecting the environment, documented and open for serious audit.
Sourcing high-quality intermediates used to mean relying on patchy imports, variable from lot to lot. Building our own process meant going through many cycles of trial and error—in line filtration mesh, reaction time tuning, and small tweaks to solvent blend ratios. We discovered that using a specific order of addition, and matching stirrer blade profiles to batch size, halted hot spots which used to create color shifts or incomplete salt formation. Many operators suggested these ideas on overtime shifts, spotting trends operators at head office never would. Even now, process improvements bubble up from hands-on work, not from consulting reports. This culture favors learning and quicker trouble-shooting, attributes that set manufacturers apart from resellers with generic product lines.
Regulatory frameworks get ever more detailed, especially for pharmaceutical ingredients. Every year, there’s another technical standard or new regional rule: digital batch traceability, identification of minor by-products, or more granular reporting of processing aids. Our company invests in digital batch records which tie every operational step back to the original raw material team. When audits come, whether for cGMP or REACH compliance, documentation comes not as a scramble but from stored records built into daily practice. For our partners in the West, traceability often makes or breaks project schedules. For end-users in developing markets, it builds the confidence that lets them focus on their own innovations rather than worry about substance origin or compliance headaches.
Our technical sales and quality control teams treat every specification tweak and suggestion seriously. More than one industry innovation started as an end-user request—a call for less residual moisture, greater bulk density, or a change in packaging material for longer shelf life in tropical climates. Customer feedback gets folded back into operations, where cross-functional groups trial adjustments in live batches. Some improvements happen within a production cycle, others take months of assessment. The result: a compound that fits the evolving needs of research, development, and brought-to-market products, rather than a static catalog entry. That feedback loop only functions with a direct line between users and the line operators, free from unnecessary layers.
Every specialty chemical faces hurdles. For this compound, the chief challenges center on maintaining stereochemical purity and managing reactions on scale, where yield falls if temperature drifts or base/acid ratios shift. The solution started with more precise control systems—autoclaves calibrated daily, monitoring with digital logs instead of clipboards. Another issue has been solvent and waste management, especially as green chemistry standards grow stricter every year. Investing in on-site solvent reclamation and switching to lower-toxicity blends cut both cost and regulatory headaches. We don’t pretend every answer is easy, but hands-on experience, real-time feedback, and a willingness to change process steps quickly have kept us ahead.
Once a customer switches to our product, the difference stands out in their workflow. Clearer NMR peaks, more consistent chromatography readings, and greater product recovery shape the daily grind of both academic and industrial labs. Several clients have told us of reduced cycle times from synthesis to testing; in some cases, overall production schedules compressed by a week per lot, simply through reduced rework and higher product acceptability out of the box. This change isn’t just incremental—it reshapes how teams plan, allowing for more aggressive project timelines and improved competitive position in fast-moving development cycles.
Industry trends drift toward molecules with more elaborate side chains, greater stereochemical definition, and bespoke functional groups tailored to specific applications. We see this compound as a building block for the next generation of pharmaceutical intermediates and biomedically active agents, areas where minor impurities or product drift can cause real setbacks. The push from generic to more patient-specific drugs calls for materials that handle stress, heat, and storage challenges without compromise. Our approach remains focused not just on volume, but on achieving repeatability and agility to serve both startup labs and global pharma supply chains. We aim to keep adapting, working in tandem with innovators and responding to tomorrow’s demands today.
For us, quality isn’t a marketing slogan. Inspection teams verify batch attributes, R&D keeps up with route improvements, packaging adapts to shelf-life challenges—all to make sure the product delivered matches or beats the promise in the data sheet. If we spot a deviation, we make the batch right, learning from the issue instead of hiding it. This approach costs more in short-term resources but pays off in customer trust, repeat orders, and a reputation that brings partnerships from around the world. These hard-earned results keep us focused, grounded, and ready for the next technical or commercial challenge.
Unlike trading houses or middlemen, owning the process lets us ramp up or dial down output to match real-world needs. During the last global supply crunch, holding full control over key intermediate synthesis steps allowed us to weather input price spikes and continue filling orders when others fell short. It takes years of forward planning and a willingness to carry higher raw material inventories than finance officers might prefer, but that margin keeps customers running—a fact confirmed by direct dialogue since the dust settled. Our promise is straightforward: as long as demand persists, so does the supply.
Walking our own production line, the difference between being a manufacturer and a broker comes down to touch, smell, sight, and record. Employees watch each step, drawing from deep experience to meet both traditional protocols and shifting user needs. Each packed drum, every sealed flask—these are more than inventory units. They carry the reputation of everyone involved, from raw material handlers to logistics planners. We stand by the belief that responsible manufacturing, fraud-free supply, and a readiness to improve with every batch will outlast trends and withstand scrutiny from both customers and regulators for years to come.
We welcome engagement from technical teams, procurement specialists, and research partners who want to know more about the inside workings and day-to-day realities of this product. Insight, mutual respect for each other’s roles, and honest communication form the backbone of every successful relationship in this field. Our doors and lines remain open to brainstorm, troubleshoot, or share what we’ve learned through trial, error, and a staunch commitment to chemical manufacturing excellence.
