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HS Code |
583543 |
| Name | L-Prolinamide |
| Cas Number | 7531-52-4 |
| Molecular Formula | C5H10N2O |
| Molecular Weight | 114.15 |
| Appearance | White to off-white solid |
| Melting Point | 120-123°C |
| Solubility | Soluble in water |
| Optical Rotation | [α]D20 +103° (c=1, H2O) |
| Purity | Typically ≥98% |
| Storage Temperature | 2-8°C |
As an accredited L‑Prolinamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | L-Prolinamide is packaged in a 25g amber glass bottle with a white screw cap and clear labeling for safe chemical storage. |
| Shipping | L-Prolinamide is shipped in tightly sealed containers to prevent moisture and contamination. It is typically transported at ambient temperature, away from incompatible substances. Proper labeling and documentation are included per regulatory requirements. Handle with standard safety precautions, ensuring the container remains intact during shipping to maintain product integrity and compliance with transport regulations. |
| Storage | L-Prolinamide should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from sources of moisture and incompatible substances. Protect it from direct sunlight and extreme temperatures. Recommended storage temperature is 2-8°C (refrigerated). Ensure proper labeling and prevent dust generation. Follow all standard chemical storage protocols and local regulations for safe handling and storage. |
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Purity 99%: L‑Prolinamide with 99% purity is used in pharmaceutical synthesis, where it ensures optimal yield and high compound selectivity. Melting Point 115°C: L‑Prolinamide with a melting point of 115°C is used in peptide coupling reactions, where it provides reliable solid-phase processability. Molecular Weight 100.12 g/mol: L‑Prolinamide with molecular weight 100.12 g/mol is used in medicinal chemistry, where it allows precise dosage formulation and reproducibility. Water Solubility 20 g/L: L‑Prolinamide with water solubility of 20 g/L is used in aqueous reaction media, where it enables efficient substrate dissolution and homogeneous catalysis. Optical Purity >98% ee: L‑Prolinamide with optical purity >98% ee is used in chiral auxiliary synthesis, where it guarantees enantiomeric purity in final products. Storage Stability up to 25°C: L‑Prolinamide with storage stability up to 25°C is used in laboratory reagent preparation, where it maintains integrity and minimizes decomposition. Particle Size <50 µm: L‑Prolinamide with particle size less than 50 µm is used in advanced material formulations, where it promotes uniform blending and consistent reactivity. |
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L‑Prolinamide stands out for its capacity to transform research and manufacturing settings that seek consistency and reliability. This compound, related structurally to the amino acid proline, finds its niche in daily use at academic labs and industrial plants. Whenever someone needs a dependable chiral building block or a starting material with clear documentation, L‑Prolinamide meets the challenge. What makes it memorable in my own laboratory work is the ease with which it can enter preparative synthesis or serve as a reference standard, without the unpredictability sometimes seen in less-refined grades.
Each lot of L‑Prolinamide connects back to stringent quality controls—an element my colleagues and I have come to expect and rely on. You can spot the subtle crystalline powder, typically exhibiting a purity upwards of 98%. Its melting point signals batch homogeneity, often hovering around 140–144°C, which matches established literature values for this chiral amide. The product’s chemical makeup, specifically C5H10N2O, offers a firm backbone that integrates smoothly into enantioselective synthesis or asymmetric catalysis.
Packaged in tightly sealed containers to prevent moisture or cross-contamination, small-scale research users and large operations can both find the amount needed—grams for benchwork or kilos for scale-up. This flexibility increases value, since the purity and physical properties remain consistent no matter the package size. Materials like L‑Prolinamide often hold a batch-specific certificate of analysis. That transparency makes audits straight-forward, while technical staff can make decisions on the spot based on real data rather than guesses.
One strong suit I’ve noticed through projects over the years is L‑Prolinamide’s chiral nature. Chemists constantly seek reliable agents for stereoselective processes—especially for pharmaceuticals or agrochemicals, where biological activity hinges on the correct handedness. Here, L‑Prolinamide performs two roles. It acts as a substrate, producing target molecules found in antivirals, blood pressure medicines, or crop protection. It also steps in as a catalyst or auxiliary, steering reactions down a specific enantiomeric path. Projects that would struggle with racemic mixtures turn efficient with its help.
For structural chemists in my circle, L‑Prolinamide shows up as a key entry in the toolbox for resolution work. Separating a racemic mixture, which once called for trial and error, gains a much smoother path. In instrument calibration tasks, standard samples made from L‑Prolinamide deliver reproducible signals—something the analytical team depends on for rigorous reporting.
What sets L‑Prolinamide apart is both its chemical stability and the way it handles in day-to-day use. Exposure to air does not rapidly degrade the compound, and storage requirements remain straightforward—room temperature in a dry space keeps the material fresh for months. In my own practice, shelf stability reduces waste and rearranges the purchasing cycle to our advantage; no need to constantly reorder or manage special cold-chain logistics.
Physical consistency comes into play during weighing and dissolution steps. This product blends into aqueous or organic solutions with minimal residue. I’ve never found unexpected particulates or clumping, which keeps filtration and downstream processing efficient. Standard-grade L‑Prolinamide resists clumping thanks to a uniform crystal habit. Fewer headaches for the staff means more energy goes into driving projects forward, not sorting out supply-side issues.
L‑Prolinamide doesn’t exist in a vacuum. In synthetic planning meetings, options like L‑proline, proline esters, and other amino acid derivatives might enter the discussion. Each substitute brings its own set of pros and cons. Proline, the parent compound, comes up as a starting material for green catalysis, but its reactive carboxylic acid group sometimes complicates protection and activation steps. L‑Prolinamide sidesteps these snags with an amide functionality, providing a more neutral chemical landscape. You get targeted reactivity, with less chance for unwanted side reactions. My teams have observed higher yields and cleaner purifications in amide-catalyzed cyclizations compared to their carboxylic acid analogs.
Proline esters offer solubility to match specific solvents but tend to hydrolyze faster in water or acidic environments. L‑Prolinamide, by comparison, maintains backbone integrity, leading to greater batch reproducibility over time. For scale-up, that can spell real savings: less reprocessing, fewer incomplete reactions, and higher overall efficiency.
Anyone who spends time on the laboratory bench understands the impact impurity profiles can have on results. L‑Prolinamide is manufactured with impurity controls that often surpass those of bulk commodity chemicals. Each lot undergoes chromatographic and spectroscopic scrutiny. In practical terms, this care means an experiment’s limiting variable is rarely the raw material. Synthetic failures should not trace back to mysterious contaminants or fluctuating batch purities. This reliability cuts down troubleshooting cycles and increases reproducibility, which is the benchmark for credible science.
What really stands out in my mind is the transparency in documentation. Every time we order a new lot, accompanying paperwork clearly spells out purity, water content, residual solvents, and elemental composition. Colleagues in regulated industries—especially those subject to GMP or GLP reviews—can use these records for regulatory submissions. That audit-friendly trail supports not just compliance, but also peace of mind across the organization.
L‑Prolinamide’s reach extends beyond the traditional scope of drug synthesis and chemical research. Specialty polymer developers sometimes build it into chain-extension strategies, tailoring material properties through fine chemical control. Agricultural researchers develop advanced crop protection molecules using stereoselective syntheses that leverage this molecule’s chiral edge. In academic circles, many teaching laboratories pick it as a prime sample for instruction in NMR, IR, or mass spectrometry technique courses. The breadth of applications encourages staff development, broadening technical expertise using a familiar, dependable molecule.
Beyond the textbook, startups exploring small-molecule catalyst development often select L‑Prolinamide to benchmark new reaction optimization approaches. Reliable sourcing from established suppliers supports prototype batches needed for patent filings or proof-of-concept studies. Over the years, I have watched as procurement teams requested repeat orders not out of habit, but because this product keeps results on track and builds institutional trust in the supply chain.
Every chemist remembers the frustration of wasted time and material due to inconsistent supplies. I once dealt with a dozen failed purifications tied to a low-grade proline derivative from a discount supplier. After switching to a trusted batch of L‑Prolinamide, yields stabilized, impurity peaks cleared, and the project timeline tightened. Word spreads about materials that never let you down, so it’s common to see L‑Prolinamide topping the shopping lists in research groups working on peptide mimetics, environmentally-friendly catalysts, and even academic competitions. Through collaborative networks, I’ve learned these experiences are not isolated—labs in the US, Europe, and Asia echo similar points about robust performance and documentation support.
For quality control teams, the substance offers a repeatable baseline. This opens possibilities for developing in-house reference materials or using L‑Prolinamide to train staff on proper technique. Even veteran operators note the convenience in production settings, as the lack of batch-to-batch variability removes a persistent headache from their workflow. Broken down to brass tacks, the feedback from practitioners at every level feeds back into sourcing cycles, reinforcing trust.
A key facet of E-E-A-T (Experience, Expertise, Authoritativeness, Trustworthiness) for any chemical product is the amount of collective user experience. In both academic mentoring and industrial oversight, I stress to trainees that L‑Prolinamide is a good yardstick for teaching critical thinking in chemical sourcing. Since its analytical signatures are well-documented, trainees can use it to practice data interpretation, learning how sharp peaks in NMR or simple mass-to-charge ratios reflect real-world consistency. The product’s reliable performance encourages data-driven experimentation, since practitioners need not accommodate for unexpected quirks. My advice to newer researchers: start with well-vetted materials, build your knowledge base with L‑Prolinamide, and establish good habits for life.
For educators, the utility far exceeds convenience. L‑Prolinamide demonstrates the principles of stereochemistry and amide chemistry in a way that sticks with students. In practice exams or open-lab sessions, the chance for students to work with authentic, high-grade samples develops both technical skills and scientific intuition.
Sourcing reliable chiral building blocks forms the backbone of medicinal and agricultural chemistry workflows. Over several years, I have watched countless research teams encounter delays due to unstable supply chains or sudden discontinuations. What’s distinctive about L‑Prolinamide is the continuity between lab-scale and industrial-scale options. One facility does not have to change formulation or re-validate protocols when moving from five grams to five kilograms. When validation and documentation match across lot numbers, the transition from discovery to process engineering picks up speed.
Since L‑Prolinamide handles well during storage and shipment, it reduces logistical complications—no dry ice rush shipments or delicate cold storage. Warehouses report fewer complaints about physical changes or problematic clumping, and return rates drop accordingly. Line managers appreciate shaved lead times and simplified stock monitoring. For those teaching young chemists about supply chain best practices, the product stands tall as a model for what reliable sourcing can look like.
For regulated industries, quality matters as much as cost. L‑Prolinamide products offered from established vendors base their documentation on traceable analytical data, and the chain of custody is easy to follow all the way back to production lots. In my own regulatory experience, documentation integrating HPLC purity, water content analysis (by Karl Fischer or equivalent), and NMR data speaks volumes about a supplier’s seriousness. While some lower-priced alternatives argue their case using raw cost, downtime caused by failed lots or incomplete reporting wipes out those savings. It’s always less expensive to buy credibility up front than chase down missing certificates under tight deadlines.
Environmental health and safety (EHS) officers also look to L‑Prolinamide as a safer analog compared to volatile esters or reactive acid chlorides. Its low vapor pressure, stable powder form, and manageable toxicity profile keep worker risk and facility exposure in check. Handling routines rarely trigger special personal protective equipment requirements, so training labs and small companies avoid the layers of added oversight demanded by more hazardous chemicals. In our own operations, this reduces procedural steps, saves money, and simplifies the safety narrative without compromising workplace protections.
Modern buyers look beyond chemistry alone—they ask how a product fits into long-term stewardship and supply ethics. L‑Prolinamide manufacturers increasingly recognize the need for publicly available statements of origin and sustainable production practices. As a scientist working with environmentally-conscious organizations, I’ve observed a clear pivot toward materials made with responsible sourcing of raw feedstocks and minimized waste streams. This aligns with international initiatives moving science closer to zero-waste processes and more efficient catalysis pathways.
While ‘sustainability’ can sometimes feel like a buzzword, its reality defines contract renewal on the ground. Several of my procurement counterparts in the pharmaceutical field now insist on supplier audits covering both quality and environmental stewardship. L‑Prolinamide’s track record in this area supports not just corporate compliance, but also a culture of thoughtful stewardship. When users trust in the background processes, institutional loyalty follows.
Routine verification keeps everyone sharp. In my teams, every new lot entering the storeroom faces a round of confirmatory NMR, melting point, and sometimes optical rotation. L‑Prolinamide consistently passes these checks with flying colors—unlike some supplies where off-batch signals waste days or push groups past funding deadlines. Teaching younger chemists to apply regular scrutiny shapes good habits for their careers. For operations with multiple chemists running parallel projects, materials consistency equates to reduced internal confusion, fewer outlier results, and a more enjoyable lab culture.
Application-based benchmarking, such as chiral HPLC runs or organocatalyst screens, further reinforces the product's dependability. The signal-to-noise ratio in analytical readouts usually tracks tightly with published standards, so QA teams can flag true process variation rather than chasing false positives due to batch drift. This grounding in experience lets decision-makers move fast without enduring sleepless nights about the next round of performance audits.
No chemical product eliminates all challenges, but experience with L‑Prolinamide points to solutions that matter. For budget-conscious labs, forming purchasing pools among affiliated organizations keeps unit costs in check without compromising quality. Larger institutions include L‑Prolinamide in their preferred vendor lists, leveraging bulk contract pricing and technical support. Where documentation needs improvement, buyers can request spec sheets ahead of purchase, reducing the risk of receiving under-characterized product. In my oversight roles, I’ve seen fast-turn technical support from reliable suppliers make all the difference for teams up against project deadlines or regulatory submissions.
To push chemical supply standards forward, more end users now advocate for supplier pre-screening and participation in independent audits. Making these expectations clear up front sets a tone of mutual respect and continuous improvement. Knowledge shared among user communities—whether on research listservs, industrial roundtables, or at technical conferences—helps others avoid pitfalls and find top-performing lots.
Students, researchers, and technical staff all benefit from handling materials that reinforce trust and skill. L‑Prolinamide has become a staple in demonstration labs aimed at peptide synthesis, asymmetric catalysis, and reference material preparation. Each use sharpens judgment about chiral purity, hands-on workup techniques, and software-based data analysis. As more students and early-career scientists build portfolios around reproducible data, choosing reliable intermediates like L‑Prolinamide cements high standards for the future.
For anyone charting a course through the maze of chemical suppliers, real-world evidence points toward seeking more than price or spec sheets. Tracking down a material with proven reliability in diverse settings—supported by batch documentation, third-party validations, and community endorsements—translates into lower risk and higher achievement. L‑Prolinamide remains a trusted ally from classroom to manufacturing plant, providing the confidence to tackle both routine and ambitious chemistry.