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HS Code |
277928 |
| Chemical Name | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt |
| Alternative Names | Bicine Sodium Salt |
| Molecular Formula | C6H12NNaO4 |
| Molecular Weight | 185.15 g/mol |
| Appearance | White crystalline powder |
| Solubility In Water | Freely soluble |
| Ph Range | 7.6 - 9.0 (for buffer solutions) |
| Cas Number | 52205-64-4 |
| Storage Temperature | Room temperature |
| Boiling Point | Decomposes before boiling |
| Melting Point | Approx. 191-194 °C (decomposition) |
| Synonyms | Sodium Bicine, N,N-Bis(2-hydroxyethyl)glycine monosodium salt |
| Usage | Buffering agent in biochemistry |
| Stability | Stable under recommended conditions |
As an accredited N,N-Bis(2-hydroxyethyl)glycine Sodium Salt factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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Purity 99%: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with purity 99% is used in clinical diagnostic reagent formulations, where it ensures minimal background interference and high assay sensitivity. Molecular Weight 207.18 g/mol: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with molecular weight 207.18 g/mol is used in protein electrophoresis buffers, where it provides precise control over migration rates. pH Stability Range 7.5–9.0: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with pH stability range 7.5–9.0 is used in enzyme stabilization solutions, where it maintains optimal enzyme activity during storage. Solubility >100 g/L in water: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with solubility >100 g/L in water is used in biochemical buffer preparations, where it guarantees homogeneous and reproducible dissolution. Endotoxin Level <0.1 EU/mg: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with endotoxin level <0.1 EU/mg is used in cell culture systems, where it prevents adverse cellular responses and maintains cell viability. Storage Temperature 2–8°C: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with storage temperature 2–8°C is used in long-term research reagent inventory, where it preserves chemical integrity and prolongs shelf life. |
| Packing | Sealed in a 500g white HDPE bottle with a screw cap, featuring a chemical label with hazard and handling information. |
| Container Loading (20′ FCL) | 20′ FCL: 18 metric tons packed in 720 plastic drums, each 25 kg net weight, for efficient, secure international chemical shipping. |
| Shipping | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt is typically shipped in sealed, moisture-resistant containers to prevent contamination and degradation. Store and transport at room temperature, away from strong acids and oxidizers. Ensure containers are labeled properly, and handle in accordance with relevant safety and regulatory guidelines for laboratory chemicals. |
| Storage | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong acids and oxidizers. Protect from moisture and direct sunlight. Storage temperature should be room temperature (15-25°C). Ensure containers are properly labeled and handled according to appropriate chemical safety guidelines. |
| Shelf Life | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt typically has a shelf life of 2–3 years when stored in a cool, dry place. |
Competitive N,N-Bis(2-hydroxyethyl)glycine Sodium Salt prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615365186327 or mail to sales3@ascent-chem.com.
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Each morning around the plant, before the piping even warms up or new batch paperwork drops on the control desk, we handle N,N-Bis(2-hydroxyethyl)glycine Sodium Salt like old friends. Our team doesn’t just make it—we watch every detail. Over the years, working with this particular chelating agent, we’ve seen firsthand how careful control at each step makes the real difference. From raw material to finished drums, this isn’t just another salt. Every small inconsistency shows itself in downstream use, so we approach every batch with the kind of measured routine you’d expect from folks who live by their quality results.
Pure chemistry never leaves room for shortcuts. This sodium salt, often recognized as Bicine sodium, stems from the unique structure created by our reaction controls. That specific molecular balance—achieved through well-timed pH corrections and temperature management—boosts buffering capacity and supports stability even in biologically sensitive conditions, like those encountered in some of the most demanding industrial and research setups.
Lots of people ask about the benefits over other buffer agents. Whether you're talking Tricine or even basic glycine salts, the answer always sits in the actual use case. Bicine sodium holds tighter pH control in the near-neutral range, which helps keep biological samples steady and enzymatic reactions reliable. We don’t just say this because we sell it. Year after year, we keep records from customers running everything from protein purification to clinical diagnostics, and we see their results improve when the buffer remains steadfast—without unexplained drifts or side reactions. Whenever troubleshooting, the field always comes back to this: a buffer with a stable, known backbone changes the reliability of any sensitive application.
Our operators and QC chemists deal with each batch like it matters—because it does. Every shipment brings with it the legacy of the work behind it, right from the initial charging of the reactor to final drying. How we monitor for residual starting material, chelating activity, and consistency in sodium content all serves to support real-world use. At the bench, even a small excess of impurities can make a night and day difference, especially in cell-free systems or analytical testing. Our best batches have one thing in common: no surprises during application, just reliable, repeatable reaction profiles.
Some products have a way of hiding their strengths until things go wrong. Bicine sodium’s value appears mostly on the tough days—the times contamination derails a protein elution or when pH spikes ruin costly samples. In our experience, keeping the final product free of heavy metals and providing a consistent sodium content changes customer outcomes from random to predictable. The peace of mind here doesn’t just come from a line on a certificate; it comes from months of unbroken runtime on demanding lines, less rework, and fewer wasted runs.
There’s something to be said for knowing exactly where your chemicals come from. Too often in manufacturing, folks run into trouble sourcing buffers off-the-shelf, especially if those suppliers move from one contract packager to another or substitute materials for the sake of price. Over the years, we’ve watched as inconsistent products led to inconsistent performance. So we took the longer route—developing and refining an in-house process that lets us keep every control lever in our hands.
That decision didn’t just protect our reputation. Customers who rely on our sodium Bicine get the same quality over time, batch after batch, because our raw material inputs, process waters, and finishing steps never change without strict reevaluation. We've discarded more than a few drums that just didn't meet our established benchmarks, because we decide what good enough looks like—not a spreadsheet halfway across the world.
Within the world of buffer solutions, this molecule plays a quiet but critical role. We’ve worked with teams developing in-vitro diagnostic assays, where the margin for error sits just above zero. One slip on pH or a surprise ion popping up can undercut months of development. In cell culture, where contamination or drift is the bane of consistency, our customers count on the same batch-to-batch behavior; the sodium salt format dissolves predictably and doesn't leave stubborn residues or floating precipitates.
Beyond biochemistry labs, we see this buffer cropping up in more specific settings: electrophoresis, enzyme stabilization, and even as a chelator in specialized metal analyses. Each use ties back to the core traits—consistent pH regulation and strong metal complexing—even with repeated or extended exposure. On the manufacturing side, we've learned how even minor tweaks in crystalline structure or moisture content change how easily customers dissolve, mix, and handle this powder. That’s why our team checks for flow, appearance, and pack integrity every time, long before anything leaves the plant.
Our plant floor and offices aren’t far apart, and that means our science, production, and customer support folks hear from each other daily. Feedback loops start on the phone or over email and often wind up back in the lab for minor tweaks or more rigorous spot-checks. It’s not theory: every adjustment—new drying times, filter swaps, better storage practices—shows up in how users report their experiences.
Over time, patterns became clear. Customers running GLP or cGMP operations demand more than just technical specs—they want assurance, documentation, and open communication about the rare hiccups. We write detailed batch records and send out supporting analytical docs because we’d want the same for our own research. Occasionally, a customer needs tighter limits on trace contaminants, or maybe a special packaging configuration. Our willingness to accommodate starts from the ground up—if it fits process safety, we make it happen, then rigorously log those changes for transparency.
You can read a table of specifications anywhere, but facts matter most when they’re practiced, not just printed. Our sodium salt falls within the standard analytical range for Bicine buffer salts, but over time, we focused on what real-world labs and industrial setups value most. That means particle size designed for rapid dissolution—not too fine so it cakes, not so coarse it leaves chunks. Our aim centers on purity, so we monitor for negligible levels of organic by-products and maintain consistent sodium ion presence batch after batch.
Purity data, heavy metal limits, and absence of microbial contamination serve as our benchmarks, backed up by recent test runs and third-party validations. The most meaningful improvements—reducing water content, capturing trace metals, screening for unexpected cations—grew from customer conversations and long-term supply relationships. Nothing comes from generic specifications alone; each one was set in response to real needs we observed or heard about directly.
Enthusiasm for improved buffer solutions ebbs and flows with industry trends, but demand for reliability never fades. Sometimes, folks ask about differences between our Bicine sodium and similar products, especially those coming from trading houses or lesser-known repackers. From where we stand, consistency remains the dividing line. Inconsistent raw materials or uncontrolled process swaps introduce risk—unnoticed until you’re troubleshooting a failed assay or inconsistent pilot run. Our end-to-end approach, from pre-qualified inputs to final inspection, keeps those worries at bay.
Over the years, we've had clients switch over after frustrating experiences elsewhere. They tell us about variable solubility rates, trace grains of undissolved salts in their columns, or unexplained by-product peaks in their analytics. Our technicians solve those headaches in advance, starting at plant design and continuing into every shift. In most cases, it comes down to pride in the finished product—knowing we caught issues before a customer ever sees them. That kind of engagement isn’t just a promise; it’s a production floor habit drawn from the real world.
Nobody works in a problem-free environment. On our busiest days, one batch might show an unexpected color shift or stray moisture reading. Instead of rushing a fix, our operators consult QA, pause the run, and track the anomaly to its source. By handling issues openly, we develop better blends, stronger in-process tests, and new training for incoming staff. That same approach continues externally—whether we’re advising a new customer on container storage or walking long-term partners through minute analytical differences brought about by new equipment upstream in their own process.
One concrete example: some labs need absolutely clear solutions, even in larger volumetric preparations, to avoid interference under UV or visible measurement. Through intensive process filtration and fine-tuning, we provide a material that produces solutions with minimal haze at workable concentrations, even in glassware sitting out for extended periods. This attention to detail doesn’t just show up in a marketing claim—it’s a series of daily measures, logging, and follow-up runs performed every week. The real solution sits in adapting directly to user realities.
Having a direct relationship with manufacturing means transparency at every step. Each customer talks to our production and QC leads, not a third party who reads off a standard sheet. When someone requests evidence of a specific contaminant profile, or needs documentation for a regulatory compliance review, we provide actual data and describe our process in plain language. This directness builds trust and shortens the troubleshooting cycle.
Over time, customers realize that every bag, drum, or pail bearing our mark passed hands that care as much as the end user does about the final outcome. When biopharma teams scale up from pilot batches to full campaigns, this commitment to openness becomes an asset. Problems get solved faster, education happens in real-time, and both teams learn from mutual feedback.
Traceability isn’t a buzzword for us—it’s a habit. We maintain complete run logs for each batch, linking all way back to our initial drum of starting glycine. If a user flags an issue months down the line, our digital batch history lets QA reconstruct the precise moment, environment, and input list. That kind of root cause discovery solves more problems than it creates, pushing our team to improve formulations, tweak storage conditions, or retrain staff where needed.
Long-term relationships work when everyone involved treats traceability as a two-way street. Customers can ask anything about our process, and we show how their feedback led to actual process improvements. For many, discovering a quality issue doesn’t mean a refund argument—it means a careful cross-check of facts, shared in the open, and a decision on how to improve for next time. This gives both sides confidence that the next batch, and every one after it, holds up to the same or higher scrutiny.
Global supply chains complicate how industries obtain key reagents. We’ve witnessed firsthand how unexpected global events turn routine orders into urgent calls. By controlling production in-house, with raw materials sourced from stable, audited suppliers, our facility absorbs those shocks better than most.
Our support extends further than a shipping notice. In serious backlogs, we’ve reallocated production schedules, prioritized lots by urgency, and helped clients find interim solutions—such as adjusted packaging or blended options—until full capacity resumes. These responses don’t grow from policies written in an office; they emerge from people on a manufacturing floor who know what it’s like to feel downstream pressure.
At the plant, we carry a long memory for customer feedback. Every suggestion, complaint, or creative request steers our continuous improvement cycles, from new QC protocols to investments in more advanced drying or milling equipment. The value doesn’t sit in a claim about being “best”—it lives in the reduced number of off-spec lots, the growing pool of repeat business, and feedback that motivates our techs to refine their process one detail at a time.
Each new production run represents a chance to get better. Where customers have identified pain points, we’ve worked side-by-side to address them, sometimes focusing on packaging upgrades, other times refining our cleaning regimes. It’s not always glamorous, but the visible difference shows up in end use—less downtime, smoother workflows, and fewer batch failures in the field.
Openness forms the backbone of trust. Our operations, from raw arrival to finished packout, remain open not only to audits, but to unscheduled visits and tough questions. For many customers, this cultivates partnerships, not just buyer-seller arrangements. The more involved our partners become—sharing their insights, needs, and challenges—the more we all improve. This mindset, rooted at every level of our facility, makes the difference between simply shipping a product and actively supporting breakthrough work across science, manufacturing, and analysis.
If there’s one lesson learned from years on the line, it's that small inconsistencies become big problems down the road. Every measure we take with N,N-Bis(2-hydroxyethyl)glycine Sodium Salt prevents those issues from reaching the user, whether it's a chemist tuning an assay, a manufacturer scaling up protein work, or an integrator piecing together diagnostics lines. Reliability isn’t just about hitting specs; it’s about building enough layers of assurance so that each user can focus on their challenge, not their materials.
The landscape for chemical manufacturing never stays fixed. New regulations appear, customers scale up, or a research breakthrough demands a new purity profile. Our approach—continual investment in process improvement, a willingness to document every change, and a relationship-driven support model—prepares us for whatever comes next. We know our job centers on more than just chemistry; it's about reducing unknowns for our partners, adjusting fast when requirements change, and always backing up each claim with experience and results from our own work.
True value in chemicals lives not in a certificate, but in the certainty they bring to complex work. Every drum and batch tells our story, built from years of attention, adaptation, and pride in getting the details right so others can unlock new progress.
