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HS Code |
357712 |
| Product Name | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt |
| Synonym | Bicine Sodium Salt |
| Cas Number | 1134-80-9 |
| Molecular Formula | C6H12NNaO4 |
| Molecular Weight | 185.15 g/mol |
| Appearance | White crystalline powder |
| Solubility In Water | Very soluble |
| Ph Value | Approximately 8.3 (1% solution at 25°C) |
| Melting Point | 287-289°C (decomposes) |
| Storage Temperature | 2-8°C |
| Chemical Category | Buffering agent |
| Ec Number | 214-489-2 |
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 a purity of 99% is used in biochemical assays, where it ensures high accuracy and reproducibility of analytical results. Buffering Capacity: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with superior buffering capacity is used in cell culture media, where it maintains stable pH conditions for optimized cell growth. Molecular Weight 195.17 g/mol: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with a molecular weight of 195.17 g/mol is used in protein purification protocols, where it enables precise control over buffer composition. Stability Temperature up to 60°C: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt stable up to 60°C is used in enzymatic reaction systems, where it prevents buffer degradation during prolonged incubations. Low UV Absorbance: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with low UV absorbance is used in spectrophotometric measurements, where it minimizes background interference for sensitive detection. Endotoxin Level < 0.1 EU/mg: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with endotoxin level below 0.1 EU/mg is used in pharmaceutical formulations, where it reduces immunogenic responses in injectable preparations. Solubility > 100 g/L: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt soluble above 100 g/L is used in concentrated buffer solutions, where it facilitates convenient handling and preparation of stock solutions. pKa value 8.2: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with a pKa of 8.2 is used in chromatographic separations, where it ensures optimal pH for efficient analyte resolution. Particle Size < 200 µm: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with particle size under 200 µm is used in rapid dissolution applications, where it provides homogeneous mixture formation. Heavy Metal Content < 5 ppm: N,N-Bis(2-hydroxyethyl)glycine Sodium Salt with heavy metal content below 5 ppm is used in sensitive diagnostic reagents, where it eliminates contamination risks and enhances assay reliability. |
| Packing | 250g of N,N-Bis(2-hydroxyethyl)glycine Sodium Salt is supplied in a sealed, labeled, amber plastic bottle for chemical storage. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 18 metric tons packed in 720 drums, each 25 kg net, on pallets for safe and efficient transport. |
| Shipping | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt is shipped in tightly sealed containers, protected from moisture and light. Packaging ensures chemical stability and prevents contamination. Standard shipping conditions are maintained at ambient temperature. Appropriate labeling and compliance with relevant transport regulations for non-hazardous chemicals ensure safe handling and delivery to the destination. |
| Storage | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt should be stored in a tightly sealed container, away from moisture and incompatible substances in a cool, dry, and well-ventilated area. Protect from direct sunlight and heat sources. Store at room temperature, typically between 15–25°C (59–77°F). Ensure that storage facilities comply with chemical safety regulations and are clearly labeled. |
| Shelf Life | N,N-Bis(2-hydroxyethyl)glycine Sodium Salt typically has a shelf life of 2 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.
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Working day-to-day in chemical manufacturing means solutions have to line up both with tight lab standards and with production realities. Among the compounds that routinely earn their place on our blend sheets, N,N-Bis(2-hydroxyethyl)glycine Sodium Salt stands out for its sharp performance in demanding environments. Known by some as a buffering agent and by others for its chelating abilities, this chemical has carved out a niche because of its dependable profile and flexible application.
In our controlled setting, we handle N,N-Bis(2-hydroxyethyl)glycine Sodium Salt as a white crystalline powder with a slight, characteristic odor that lets an experienced chemist spot its presence even before the label gets checked. Each lot leaves our site with standard content of the sodium salt above 99.5%, confirmed by titration and chromatography. Water content remains tightly checked, falling below 0.5% as moisture can throw off both storage stability and reaction yields.
Particle size and solubility profile get more attention than most end-users suspect—clumping or caking create headaches downstream, so the grinding, milling, and drying steps have run through years of process improvements. Once this compound moves through our final QA, you get a powder that dissolves quickly in cold water, with negligible sediment, verified in batch-level quality checks. We monitor for trace ions and contaminants like lead and arsenic, which stay well below established international thresholds and our internal benchmarks that sit lower still.
Our long-term customers in industrial and biotechnological sectors keep coming back for this product, not as a luxury inclusion but for its unique ability to stabilize pH without introducing instability or excess foaming. Complex enzymatic syntheses and fermentation processes depend on a buffering environment that won’t drift or destabilize with heat, agitation, or dilution. Regular sodium phosphate or citrate buffers show their limitations here—N,N-Bis(2-hydroxyethyl)glycine Sodium Salt extends the pH window and reduces the risk of reaction slow-down due to metal ion interference.
Researchers running protein isolation from mammalian or bacterial lysates credit this compound’s dual ability to gently chelate trace copper or nickel ions while not stripping essential divalent ions from solution altogether. Plenty of buffer salts either over-chelate or offer little actual stability. N,N-Bis(2-hydroxyethyl)glycine Sodium Salt keeps those balances running right.
Our group has watched instrumentation labs and diagnostic kit assemblers drill into the details before making the switch to this buffering agent. The difference shows most clearly in outcome reproducibility and lower correction rates: suppliers who understand how purity and trace ion levels influence ELISA plates or HPLC flow paths realize cost savings not through initial price, but decreased reruns and less troubleshooting time.
Plenty of other compounds move through our reactors and drying rooms—ACES, HEPES, Tris, and sodium phosphate fill big orders too, but each brings strengths and blind spots. Our shift foremen and QC chemists agree: no other buffer matches the unique hydrophilicity and inertness shown by N,N-Bis(2-hydroxyethyl)glycine Sodium Salt under thermal and mechanical stress.
In head-to-head trials against standard Tris or phosphate buffers, we observed fewer byproducts at elevated temperatures, even after repeated autoclave cycles. This matters in pharmaceutical and diagnostic work where small side reactions create big headaches during final purity checks. Further, in situations demanding low UV absorbance at monitoring wavelengths, Tris-based buffers have shown unexpected peaks—our sodium salt formulation does not.
Some competitors produce buffers using older tech on legacy equipment. In our facility, these reactors have been converted and validated for only pharmaceutical-grade media. We harden our process against cross-contamination through machine learning–based analytics, flagging batch anomalies as soon as one metric drifts out of spec. In our experience over the last decade, this product’s batch-to-batch consistency outruns similar compounds, leaving less troubleshooting for users down the line.
Chelating agents like EDTA certainly pull more strongly at divalent ions, but that kind of aggressive chelation can cripple sensitive biological reactions. Our N,N-Bis(2-hydroxyethyl)glycine Sodium Salt gives a milder, more controlled chelation, favored in pathways where enzymes depend on calcium or magnesium in complexed but still active states.
From a logistics point of view, this product also ships and stores with fewer carrier or hazard restrictions than many similar compounds—high chemical stability and low reactivity lower insurance hurdles for our buyers, which can matter in cost-sensitive procurement cycles. It handles temperature swings and short-term humidity spikes in storage well, something commodity buffers can't always claim.
Our manufacturing team never treats purity as a simple compliance issue. Over years of customer trials, we’ve found that small differences in salt and moisture content in a buffer have big consequences during downstream formulation or QC. For each order, we break down analytical profiles for sodium, calcium, magnesium, copper, nickel, lead, and zinc ions, along with closely watched organic residues.
While it’s possible to manufacture at 98% content, our internal policy aims for at least 99.5%. The cost per kilogram rises with the last percentage point, but customer feedback has highlighted that higher purity directly reduces process rework rates and increases yields in diagnostic kit production. Several pharmaceutical partners reported a measurable drop in batch rejection rates after switching from industrial to our pharma-grade lot.
Maintaining this level of purity is not a paper exercise—it affects every batch’s performance in real-world applications, such as sterile compounding for injectable diagnostic agents, or in-process buffer exchange during chromatographic separations. The scale of QC we apply, from titrimetric analysis to advanced chromatographic scans, ensures our sodium salt delivers the reliability laboratories require, with less batch-to-batch adjustment required downstream.
From raw material sourcing to finished product, direct control over the entire supply chain means we can track and block sources of contamination before they reach a reactor or blending vessel. Close team relationships with bulk ethylene oxide and chloroacetic acid suppliers let us align raw inputs to more exacting standards than market average. Each reactor charge gets tracked for composition, and deviations trigger immediate batch holds.
Solid-phase drying and granulation steps, managed in-house, put us in a better position compared to packagers who only repack material from external suppliers. Moisture, dust particulate, and metal impurities get filtered out long before the product meets any shipping drum or laboratory bottle. Loss-on-drying tests form part of every production run, resulting in cleaner, more stable material that stores and dissolves predictably after weeks or months in warehouse conditions.
Our teams also invest in direct feedback loops with application scientists and QC techs at the receiving end. Reports of unexpected precipitation, filter clogging, or color changes get routed right back to process engineers, who tweak upstream operations to solve root causes. These collaborations run deeper than standard technical support—they shape equipment upgrades and personnel training decisions.
A compound’s worth gets measured in the reliability it brings day in and day out. Over the years, N,N-Bis(2-hydroxyethyl)glycine Sodium Salt has repeatedly shown up as the practical choice in protein crystallization and high-precision analytical work. Supply interruptions or formula changes rarely trouble it—stability data logged across multiple climates back its performance.
End-users in molecular biology apply this buffer for DNA extraction, PCR setup, and cell culture media, where minor lot variations can compromise results. We’ve run our own bench-scale extractions and have witnessed smoother phase separations and more consistent colorimetric assay signals compared to phosphate or Tris alternatives. In fermentation control, teams employ this buffer for its resistance to drift even with constant mechanical agitation and moderate heating cycles.
Our chemical, protein, and nucleic acid customers have cited the salt’s impact not just on lab outcomes but also on process scaling, noting the quick dissolution rate and the lack of residual haze in solution. Smoother filtration and reduced backpressure during chromatography let downstream processes run longer without scraping or restarting equipment.
Feedback from our user base (biotech companies, research labs, and diagnostics firms) often circles back to the same points: low downtime, high repeatability, and reduced need for mid-process pH correction. Scale-up from bench to pilot plant stresses most buffer systems, but our sodium salt blend doesn’t flinch, minimizing headaches during batch ampoule filling or sterile media prep.
Some customers share data outlining cost/performance ratios, showing a significant drop in discarded batches due to pH drift or unexplained color shifts. Other labs, running sensitive UV-absorbance assays, have sent us overlays of baseline noise: the clarity advantages of our formulation stand out on the graphs, with lower background and reduced spiking—even at sub-millimolar concentrations.
Scale doesn’t scare this compound—one customer running 1,000-liter fermentation tanks documented near-zero drift in pH control after converting to our product. Meanwhile, a diagnostics manufacturer described a cleaner, more stable reagent composition, making maintenance checks less frequent and calibration curves more reliable across monthly production cycles.
Manufacturing and handling buffers like N,N-Bis(2-hydroxyethyl)glycine Sodium Salt brings daily challenges. Moisture exposure, cross-contamination, and raw material variability threaten any batch’s integrity. Over the past decade, our team invested in advanced monitoring—from in-line IR spectroscopy for real-time moisture feedback to automated dispensing and sealed filling lines.
Every year, we invest in incremental upgrades, learning from user setbacks and our own process mishaps. When a customer flagged precipitation in a 2018 diagnostic batch, we traced the cause to a subtle, previously overlooked magnesium carryover in a raw input. Root-cause analysis led to new sourcing controls and real-time metal ion checks before reactor loading, which eliminated the issue in subsequent years.
Climate control across multiple warehouses matters for a powder this sensitive: to keep lots stable in all seasons, our facilities use precise environmental mapping. Automated logs inform adjustments to HV/AC and dehumidification parameters; material rotation schedules get adjusted on-the-fly to match shipping conditions, whether the product is destined for humid coasts or dry continental interiors.
Our team’s experience also guides how the product gets shipped—handled in leak-proof PE drums with compressive liners, tested for sorption rates under both high and low temperatures. To fight caking and clumping in transit, we manage inbound humidity at the source, not just as a last-minute packaging decision. Customers aiming for flawless dissolution can cut their prep times by handling material stored below 60% RH and limiting open-air contact.
Lab waste and environmental impact also weigh on us as direct producers—waste reduction and better solvent recycling protocols cut down the chemical's lifecycle footprint. Partnerships with downstream users create shared value; buffered waste from purification can often be neutralized and safely treated on-site, reducing both cost and risk for partners and for us as a manufacturer.
Producing N,N-Bis(2-hydroxyethyl)glycine Sodium Salt at scale draws together a blend of backbone chemistry, careful process control, and daily learning from those who use it in everything from enzyme feedstocks to routine hospital diagnostics. Watching new regulatory standards emerge for critical raw materials, we keep adapting our process—making batch traceability and product analytics central, not optional.
Research customers require lots that match every specification, but even in bulk industrial use the fine details—moisture, trace metal content, precise buffer range—set apart each shipment. Our company answers the call for rigor and accountability, because details at the manufacturing stage shape not just compliance, but real outcomes in field and lab.
Sourcing, process, and support all align with one aim: dependable performance. Customers leveraging our manufacturing expertise find themselves able to spend less time troubleshooting and more time building out robust, scalable processes in their own production lines.
Our role as a direct manufacturer goes beyond shipping out drums or jars of N,N-Bis(2-hydroxyethyl)glycine Sodium Salt. In practice, we set internal standards higher than minimum certifications, because customers and regulatory bodies both set the bar higher with every new round of innovations in biotechnology and diagnostics.
Trends show demand for even greater batch purity, tighter control of trace contaminants, and rapid adaptation to changing specifications. We invest in both equipment and people—every process step is open to modification, every analysis open to review. We stay agile, incorporating real-world user data back into process design, ensuring each lot supports the ambitions of those working at the front lines of science and medicine.
With advances in high-throughput chromatographic and bioanalytical techniques, buffer salts like ours play an increasingly central role. Accuracy starts with chemistry managed right at the start of the supply chain. Our job, as we see it, is to make sure it stays that way.
