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All Right Reserved
|
HS Code |
117210 |
| Iupac Name | (3R)-piperidin-3-amine |
| Molecular Formula | C5H12N2 |
| Molecular Weight | 100.16 g/mol |
| Cas Number | 412335-51-2 |
| Appearance | colorless to pale yellow liquid |
| Boiling Point | 217-219 °C |
| Density | 0.96 g/cm³ (approximate) |
| Smiles | N[C@H]1CCCNC1 |
| Inchi | InChI=1S/C5H12N2/c6-5-2-1-3-7-4-5/h5,7H,1-4,6H2/t5-/m1/s1 |
| Chirality | R-configuration at position 3 |
| Solubility In Water | Miscible |
| Pubchem Cid | 10235462 |
As an accredited (3R)-3-Piperidinamine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g, amber glass bottle with a screw cap, labeled clearly with identification details, hazard symbols, and safety information. |
| Shipping | (3R)-3-Piperidinamine is shipped in secure, chemical-resistant containers, complying with applicable regulations for hazardous materials. Packaging ensures protection against moisture and contamination during transit. All necessary documentation, including safety data sheets and labeling, accompanies the shipment. Transport is arranged via certified carriers to guarantee safe and timely delivery. |
| Storage | (3R)-3-Piperidinamine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from heat sources and incompatible materials such as oxidizers. Protect from moisture and direct sunlight. Store at room temperature and ensure proper labeling. Use appropriate chemical storage cabinets if available, and limit access to trained personnel only. |
Competitive (3R)-3-Piperidinamine prices that fit your budget—flexible terms and customized quotes for every order.
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(3R)-3-Piperidinamine stands out as a versatile chiral building block, drawing attention from researchers and manufacturers who push for more efficient and reliable pharmaceutical synthesis. The name might feel technical, but what's behind that name is both potent and adaptable. This compound, often known as a key intermediate, shapes the progress of several critical molecules used in both research and production. Labs working on active pharmaceutical ingredients often pursue molecules like (3R)-3-Piperidinamine for their predictable reactivity, optical purity, and accessibility.
Chemists put a high value on stereochemistry—choosing the right configuration can make or break an entire process. (3R)-3-Piperidinamine brings the confidence of enantiomeric purity, supporting research that aims for specific biological effects and reduced unwanted side products. In this, it’s more than just a commodity: it’s a problem solver at the molecular level.
This compound appears as a white crystalline solid at room temperature. Most batches arrive with a purity of 98% or higher, and specialists will recognize its CAS number as 16495-13-9. A molecular formula of C5H12N2 describes a simple, no-nonsense structure but don’t let that fool you. Its simplicity allows for clear reactions and easier purification, two traits that make it stand out compared with bulkier, more complicated alternatives.
The melting point, typically around 48-51°C, provides a reliable window for storage and manipulation in both large-scale and small-batch operations. Solubility in water and standard organic solvents opens doors for flexible use, helping manufacturers swap it in without exhausting extra resources. In practical applications, the amine group can function as a nucleophile, and the piperidine ring offers stability not often seen in more fragile amines. This stability improves outcomes when reactions call for temperature or pH swings, letting teams work faster without the risk of losing precious material.
By experience, anyone working regularly in custom chemistry finds products like this help bridge gaps in supply chains—they don’t call for excessive purification, saving time and labor. For a small molecule, (3R)-3-Piperidinamine delivers both technical reliability and consistency, which, for most labs, counts for more than boasting about exotic specifications.
Every pharmaceutical chemist looks for that edge—what can shorten a synthesis, what gives fewer byproducts, and what gets to market safely. In countless syntheses, this amine does the heavy lifting, whether building beta-blockers, constructing antiviral backbones, or crafting CNS agents. Its chiral center gives formulators confidence when targeting enantiomerically pure drugs, which means the difference between a treatment that works and one that could cause side effects.
Outside the world of pharma, the role of (3R)-3-Piperidinamine grows in specialty polymers and advanced materials. Polymer scientists have started using it as a monomer or end-group modifier, especially where chiral properties increase the value of the end product. This trend emerges from practical observation: materials gain new life when their backbone chemistry gets fine-tuned by a reliable amine like this one.
For agrochemical R&D, this compound allows teams to invent safer, more targeted herbicides and pesticides. Its ability to modify core scaffolds gives agrochemists tools to move beyond “one size fits all” solutions, which can persist in soils and disrupt local ecology. Many industry players now see (3R)-3-Piperidinamine as a way to personalize chemical control agents for specific crops or pests, all due to the flexibility provided by its well-defined structure.
Anyone who has worked at a bench or scaled up to pilot production knows laboratory surprises complicate innovation. Channels with reliable (3R)-3-Piperidinamine supplies avoid unnecessary setbacks. Quality assurance teams always chase after batch consistency. An intermediate like this, with well-understood manufacturing routes, keeps surprises in check. Instead of spending overtime investigating process deviations, teams can focus on optimization and getting results out the door quicker.
Like many scientists, I’ve traced more than a few failures back to poorly characterized intermediates. If a molecule comes with unknown stereochemistry or trace impurities, even a minor one can derail a project. In this sense, the difference between a solid intermediate and a mediocre one is not subtle at all for practitioners. Reliable sources for (3R)-3-Piperidinamine reduce audit headaches and provide documentation for regulatory filings, all points that busy compliance managers fully appreciate.
Globalization has stretched chemical supply lines thin. The COVID-19 pandemic showed how gaps can add months or even quarters to a timeline. What makes intermediates like (3R)-3-Piperidinamine valuable is as much about dependability as about chemistry. Manufacturers who set up secure, transparent supply lines and offer tight batch-to-batch control gain trust—and that trust supports business year after year.
Faced with increasing regulatory demands for traceability, opting for intermediates with established documentation smoothes the transition in moving innovations from lab notes to commercial production. There’s less guesswork and more room for value-added R&D, all thanks to robust, well-characterized input materials.
With so many amine options available, purchasers and formulators want to know why one stands out. Many turn to derivatives like (S)-N-methylpiperidine or use unsubstituted piperidine for cost. The clean chiral center in (3R)-3-Piperidinamine offers a decisive advantage for syntheses aiming at single-enantiomer drugs. Racemic mixtures force chemists to separate out the desired part, wasting both time and resources.
In several routes, using other piperidine-based amines drags in extra steps. Achiral analogs might require post-synthesis resolution, or risk making less targeted, less safe drug candidates. Comparing bulk stability, (3R)-3-Piperidinamine resists racemization through standard lab or production conditions, so formulations stay true through each stage of manufacturing. That trait helps chemists avoid having to scrap or rework batches, saving both money and morale.
Given its popularity for optically active compounds, some worry about price or access. Still, broad adoption has encouraged more manufacturers to produce this intermediate, with several high-quality sources available globally. Buyers often find the increased up-front cost is offset by reduced downstream rework and higher product yield. For those running lean teams, efficiency at stage one pays off rapidly.
Compared to classic piperidine, this configuration brings a depth of functionalization options. Chemists exploit that to tailor functional groups, design better prodrugs, and access more advanced scaffolds. Its ‘plain’ amine relatives don’t always offer this breadth—making (3R)-3-Piperidinamine a top pick for those chasing versatility as well as reliability.
Wider conversation in chemical supply now revolves around both quality and sustainability. Unexpected contamination incidents in the past have led to recall after recall, placing the spotlight on responsible sourcing. Suppliers now publish transparency reports and offer tracking info from raw material to finished good, making it easier for teams to audit and verify.
(3R)-3-Piperidinamine benefits from established production methods that avoid hazardous reagents, which aligns well with growing calls for greener chemistry. Disposal and transportation present fewer challenges compared to amines with halogen or metallic impurities. In production circles, these “hidden costs” show up on bottom lines whether anyone wants to admit it or not. By choosing this amine, buyers benefit from reduced handling risks and a smaller environmental burden.
I’ve watched this shift up close. Manufacturers who embrace more transparent, eco-friendly supply chains see fewer interruptions. With environmental regulations tightening, especially in the EU and East Asia, material traceability can mean the difference between thriving and having product lines shuttered over paperwork. Those who plan ahead with choices like (3R)-3-Piperidinamine insulate their research groups, manufacturing lines, and even marketing strategies from regulatory whiplash.
The best returns on investment come from understanding upstream and downstream impact. Teams that build relationships with suppliers, ask the right questions about process validation, and demand accessible QC documentation see smoother development cycles. For small startups, that solidity allows more risk-taking on new therapies. For larger players, it means cleaner audits and stronger IP positions.
Real-world experience also shows savings mount faster than expected when projects avoid unnecessary remixing or purification. I’ve been on projects where one supply of a reliable amine let us prototype four times more drug candidates with half the labor, simply because purification and analysis followed predictable paths. That sort of time gain often spells the difference between catching a market window or being caught outside looking in.
Project managers sometimes overlook the power of documentation. Modern users benefit from detailed COAs, audit trails, and stability data. These reports don’t just satisfy a “tick-the-box” mentality—they guide troubleshooting, help predict shelf life, and provide the reassurance project teams need to invest further. Well-crafted intermediates like this become silent partners on development journeys, absorbing complexity and delivering measurable value.
Regulation shapes nearly every aspect of chemical process design, especially in the pharma sector. It surprises some newcomers just how early compliance requires attention. From raw material specification to impurity tracking, regulatory teams scrutinize every choice. Intermediates backed by up-to-date documentation speed up regulatory checks, contributing to faster time-to-market for critical therapies.
For controlled substance synthesis, tracking chiral intermediates keeps research within permitted boundaries. (3R)-3-Piperidinamine’s well-documented manufacturing pedigree makes it easier to demonstrate conformity with international standards. Over the years, I’ve watched projects bog down over uncertainty in the precursor supply. Products like this, with a long history of safe, transparent use, shorten those deliberations and help teams stay on track.
Process engineers also see measurable advantages in safety and waste generation. Less time spent on rework means labs generate fewer solvent streams, produce less waste, and answer fewer questions from environmental monitors. Picking robust intermediates helps new process designs avoid red flags and earns them credibility with both internal and external auditors.
Grassroots feedback often steers procurement and R&D, sometimes more than glossy brochures ever could. Conversations with peers at conferences point to one theme: consistency pays. Product managers praise the predictable performance. Lab staff report fewer rejected lots. For teams working on tight turnarounds, stability is more than a feature—it becomes the reason a compound gets specified again and again.
Much of (3R)-3-Piperidinamine’s success comes from real-world validation. Networking with others in the field often leads to stories about how a single lot let an entire project pivot from hit-or-miss to ahead of schedule. By combining trusted feedback and supplier transparency, research directors can build a portfolio with fewer worries about unexpected upsets. In today’s competitive landscape, every advantage counts.
Looking forward, chemists and drug designers will keep demanding higher quality and adaptability from their building blocks. The move toward green chemistry and targeted therapies makes intermediates like this even more important. As research pivots towards specialty molecules with tailored actions, the value in robust chiral intermediates will only increase.
Innovation thrives where teams trust their inputs. (3R)-3-Piperidinamine continues to be at the forefront, not just for legacy projects but also for the next generation of specialty chemicals and medicines. It fills a gap left by more generic, less-predictable reagents, giving projects a stronger footing from the start.
By working with intermediates that support both quality and compliance, organizations set themselves up for success—both in regulatory environments and in the rapid development cycles demanded by modern markets. The lesson, learned across many late nights in the lab, rings clear: solid inputs make strong outcomes.
