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HS Code |
796781 |
| Chemical Name | Serinol |
| Iupac Name | 2-Amino-1,3-propanediol |
| Molecular Formula | C3H9NO2 |
| Molar Mass | 91.11 g/mol |
| Appearance | White crystalline solid |
| Melting Point | 56-58 °C |
| Boiling Point | 219 °C |
| Solubility In Water | Very soluble |
| Cas Number | 534-03-2 |
| Density | 1.187 g/cm³ |
| Odor | Characteristic |
| Pka | 8.1 (amino group) |
| Flash Point | 158 °C |
| Synonyms | 1,3-Dihydroxy-2-aminopropane |
As an accredited Serinol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Serinol is packaged in a 500g amber glass bottle with a secure screw cap, featuring clear hazard labeling and product information. |
| Shipping | Serinol should be shipped in tightly sealed containers under cool, dry conditions, away from incompatible substances such as strong oxidizers. Ensure proper labeling and compliance with local, national, and international transport regulations. Protect from physical damage during transit, and use appropriate protective packaging to minimize risk of spills or contamination. |
| Storage | Serinol should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers. Protect the chemical from moisture and direct sunlight. Proper labeling and secondary containment are recommended to prevent leaks. Always follow standard chemical storage protocols and consult the safety data sheet (SDS) for specific storage instructions. |
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Purity 99%: Serinol with 99% purity is used in high-performance epoxy resin formulations, where it ensures enhanced mechanical strength and chemical resistance. Molecular weight 91.11 g/mol: Serinol of 91.11 g/mol molecular weight is used in polyurethane synthesis, where it allows precise control over polymer chain length and flexibility. Viscosity grade low: Serinol of low viscosity grade is used in waterborne coatings, where it promotes better substrate wetting and uniform film formation. Stability temperature 120°C: Serinol with a stability temperature of 120°C is used in heat-cured adhesive systems, where it maintains its structural integrity during thermal processing. Melting point 54°C: Serinol with a melting point of 54°C is used in hot-melt adhesives, where it enables rapid application and setting at moderate temperatures. Particle size <10 µm: Serinol with particle size below 10 µm is used in pigment dispersion applications, where it delivers improved suspension and color uniformity. Hydrophilicity high: Serinol of high hydrophilicity is used in water-soluble polymer formulations, where it increases solubility and homogeneous mixing. Reactivity index high: Serinol with a high reactivity index is used in crosslinking agent production, where it accelerates curing kinetics and boosts final crosslink density. |
Competitive Serinol prices that fit your budget—flexible terms and customized quotes for every order.
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In a marketplace crowded with vague promises and distractions, Serinol stands apart as a straightforward, hard-working offering for those who value transparency. This product isn’t trying to be everything to everyone; it focuses on doing its job, and doing it well. Drawing from time spent both in the workshop and in the research lab, I recognize the feeling of finally coming across a product that gives more than just marketing buzzwords. Serinol exists for those who understand that, in the end, it’s what happens when the tool meets the task that actually matters.
Serinol comes as a clear, viscous liquid at room temperature, and many in the chemical, pharmaceutical, and cosmetic fields have come to depend on it for daily work. Chemically, it’s known as 2-Amino-1,3-propanediol. The typical grade available today offers a purity of over 99%, aiming to meet the sort of standards that researchers or manufacturers expect in demanding environments. The molecular formula, C3H9NO2, and its manageable molecular weight of 91.11 g/mol, tell part of the story, but the more telling details come from how it actually performs in the hands of real users.
Folks in labs or manufacturing facilities spend little time with products that gum up equipment or introduce contaminants into the end product. Serinol dissolves readily in water, mixes smoothly in a variety of solutions, and doesn’t bring a noticeable odor, which makes life easier for lab staff and operators alike. Having personally worked on formulation projects, I’ve found Serinol mixes clean, with little need for excessive adjustment. This saves time and resources, which always seems like a scarce commodity.
Serinol’s main competitors tend to be compounds like glycerol, ethanolamine, or triethanolamine. Glycerol, with its sticky residue and slower evaporation, finds favor in certain thickening applications, but Serinol offers more flexibility in pH control, buffering, and biocompatibility. In direct comparison, ethanolamine brings more volatility and sometimes pungent odors; triethanolamine, while useful, comes with added regulatory discussion in some parts of the world. Serinol avoids these headaches, giving users a layer of safety and comfort in applications where contact with skin or biological material is common.
Having watched production teams try to substitute other compounds and run into headaches around purity and regulatory standards, I can say with confidence that Serinol often offers smoother approval from both internal quality assurance and outside agencies. It often slips through review processes with less discussion simply because industry teams recognize the ingredient and trust its provenance.
In pharmaceuticals, Serinol fills a clear need in buffer systems, injectable solutions, and topical creams. Doctors, pharmacists, and technicians appreciate that it tends to avoid hypersensitivity responses when used at common concentrations. For cosmetics, formulators reach for Serinol to build moisturizers, serums, or hair-care products that maintain gentle profiles for users with sensitive skin. In personal care, end-users tend to report “less stickiness,” better feel, and fewer breakouts, echoing the experiences I’ve heard from both researchers and product testers.
Biotechnological research labs also keep Serinol close at hand for protein crystallization and cell culture work. It supports clear, predictable results, so data doesn’t get thrown off by batch-to-batch inconsistency. That sort of reliability matters deeply to teams balancing deadlines and grant requirements.
Every material tells you something under stress. What I’ve seen with Serinol is a welcome stability over a wide temperature range. It stays manageable in both heated and chilled environments, so storage options open up, which proves crucial for smaller labs or companies that lack industrial facilities. Its resistance to degradation under both light and moderate contamination (within reasonable bounds, of course) means the shelf-life tends to outlast most direct substitutes, cutting down on waste and last-minute reordering. This isn’t just about dollars and cents—although those matter, too—it’s a question of keeping projects moving without interruption.
Lots of the worry around new chemical products comes from a lack of long-term toxicity data or messy stories in the news. Serinol steps into this field with a solid history. The available literature and regulatory profiles, especially in the US and EU, point to a low risk from both acute and chronic exposure when handled within recommended guidelines. I’ve seen occupational safety teams breathe a sigh of relief knowing Serinol’s safety record backs up the product sheet, not just the sales pitch. Serum, tissue, or dermal tests all back up this safer profile, giving formulators a way to meet regulatory hurdles on the first try more often.
Some alternatives ask formulators to make tradeoffs between performance and exposure risk. With Serinol, choosing between safety and effectiveness doesn’t come up as often. In my time working alongside safety officers and regulatory consultants, it was clear that having more ingredients in the “low concern” category makes everyone’s life easier—right from R&D through batch approval.
To make an informed choice, buyers want to know more than just price per kilogram. Reputable suppliers of Serinol back up every shipment with batch certifications and clear traceability. My own experience sourcing fine chemicals for a mid-sized lab drove home how often logistics and paperwork can trip up well-planned projects. A clean paper trail, coupled with in-house or independent third-party testing, means quality doesn’t rely on blind trust.
Leading producers offer not just standard COAs, but batch histories, impurity profiles, and often the flexibility to tailor packaging and transportation options to facility needs. That isn’t just a tick-box exercise; it reflects a culture of respect for the people who’ll use, move, and clean up after these materials.
Choices matter far beyond the plant walls or benchtops. The sustainability footprint of a product rarely gets discussed up-front, but more businesses and universities—my own included—face increasing pressure to justify every compound on environmental grounds. Serinol appeals to anyone who cares about downstream effects. It breaks down quickly in water and soil, so persistence and bioaccumulation don’t sit on conscience or compliance audits.
Growing focus on green chemistry means that less hazardous, more biodegradable materials win points in procurement meetings. The manufacturing routes for Serinol have shown improvement in energy use and waste management over the last decade, steadily reducing their impact. While no industrial product is perfect, progress gets noticed—and makes a difference in who gets the purchase order.
No product solves every challenge, and Serinol presents its own boundaries. For some dry formulations or solvent-heavy processes, other candidates may edge ahead on cost or convenience. Those pushing for the lowest possible purchase price—especially outside regulated markets—sometimes pick less refined substitutes. But in regulated industries or high-end research, the calculation tips back toward Serinol for its clean profile and predictable results.
Researchers continue investigating the compound’s use in new medical applications and advanced materials, but adoption sometimes bumps into tradition and conservatism. It takes time—and direct comparisons—to convince teams to switch out tried-and-true ingredients for something a little newer but a lot more robust on safety and sustainability.
Conversations with product engineers, formulation scientists, and lab managers boil things down quickly. It’s not about the latest marketing material, but about how a material responds on a busy Tuesday afternoon. Time and again, I’ve heard comments on Serinol’s consistency—batch quality stays where it should without annoying surprises. Operators don’t complain about cleanup later, and department heads spend less time on out-of-spec rework. The bottom line shows up in easier audits, smoother process validation, and fewer late-night problem-solving sessions.
Industries move forward by choosing building blocks that make good results more likely, instead of rolling the dice with unknowns. For teams looking to cut risk and streamline approval, Serinol offers a trusted tool. Investing in collaborative research will stretch its boundaries further—think improved topical delivery, novel biomaterials, or smarter cosmetic blends. Sharing more open, post-market surveillance on real-world outcomes strengthens trust for the next wave of users.
Procurement teams can push for supplier transparency, refusing to accept batch variability or gray-market sourcing. Buyers have more clout than they often realize; by demanding strong documentation and open dialogue, the whole sector benefits. On the regulatory side, agencies working with industry scientists could learn from how Serinol handles both the technical and practical realities, using proven compounds as blueprints for judicious, evidence-driven approval frameworks.
Educators and labs at colleges can build Serinol into hands-on learning about safe chemical handling, buffer systems, and formulation principles. That way, the next generation meets usable, modern compounds before hitting the commercial workforce. I’ve seen student projects run smarter thanks to having access to clean, reliable materials like this, instead of outdated or questionable substitutes.
Serinol doesn’t lay claim to revolutionary status or claim miracle properties, but it delivers on what it promises: cleanliness, practicality, and a low-hassle safety profile. As regulatory pressure builds on manufacturers to keep people and the environment safe, and as end-users grow more concerned with the sources of what they touch and use, the future looks bright for those who choose their products based on real experience and hard-won trust. My years working across the chemical and manufacturing spectrum taught me to look at what consistently reduces headaches, scores points with both QA and users, and doesn’t leave a chemical legacy behind. On those counts, Serinol deserves a place on the shelf.
As we look for better ways to build the essentials of modern life, Serinol offers a practical, evidence-backed choice. This product reminds us that progress often means finding the right ingredients and working with suppliers and regulators to keep raising standards, one batch at a time.
