MES Sodium Salt comes from the group of sulfonic acid derivatives. Its systematic name is Sodium 2-(N-morpholino)ethanesulfonate. The molecular formula stands as C6H14NO4SNa. This compound features a morpholine ring linked by an ethyl bridge to a sulfonate group, creating a zwitterionic structure at certain pH ranges. Its molar mass is about 217.24 g/mol. The layout of atoms grants MES Sodium Salt excellent buffering capabilities, helping keep pH levels steady in biological and chemical experiments.
The physical properties of MES Sodium Salt can make a big difference in lab work and manufacturing lines. In its most encountered form, MES Sodium Salt looks like a solid, white crystalline powder or, less commonly, as flaky or granular solids with a faintly off-white hue. The compound dissolves readily in water, delivering solutions that stay clear and colorless, especially when concentrations stay below 1 molar. It carries high density for a buffer salt, with a specific gravity around 1.5–1.6 g/cm³. The melting point sits above 300°C. Handling a kilo of fine powder or a scoop of coarse flakes calls for consistent safety gear, though MES Sodium Salt does not emit hazardous vapors or strong smells. You find it in bags, jars, or drums, with storage at room temperature out of direct sunlight.
In the field and the lab, MES Sodium Salt takes on the role of a buffer, especially for cell culture, protein purification, and biochemical assays where pH stability around 6.0–7.5 is crucial. The buffer keeps enzymatic reactions reliable, safeguards protein structure, and maintains living cells’ healthy environment during tests. The purity of MES Sodium Salt matters in biology and pharmaceuticals. Impurities, even in the parts-per-million range, are unwanted in high-stakes research, so batches undergo tight quality control, with specification sheets reporting purity above 99% by titration, heavy metals below 10 ppm, and minimal moisture content. Manufacturers usually provide safety data sheets covering handling, exposure limits, and disposal.
MES Sodium Salt appears as a microcrystalline powder, chunky flakes, or uniform pearls—it all comes down to processing methods. Large-scale orders sometimes arrive as dense, loose powder or hard-packed crystals. Dissolved, MES Sodium Salt gives stable, neutral pH solutions used directly in sensitive experiments. The choice between powder, pearls, or solid forms often depends on dissolution speed in water, shelf life, or storage demands. Powder and flakes offer the flexibility to weigh exact amounts, pearls reduce dust in air, and liquid concentrates support fast batch-to-batch prep. Inside the plastic or glass bottle, every grain represents the backbone of experiments trusted by academic researchers and manufacturers alike.
As a chemical, MES Sodium Salt sits in a gray area for risk. The compound does not cause burns or severe reactions in small volumes. Nonetheless, contact with eyes or skin can bring irritation if left unwashed. Swallowing moderate amounts can upset the digestive tract. Like many chemicals, the greatest threat comes not from the compound itself but from repeated inhalation of dust, allergic reactions, or improper storage with incompatible acids or oxidizers. Safety data sheets summarize the key points: use gloves and goggles during transfer and mixing, have running water nearby, and avoid direct contact for extended periods. Fire risk stays low, but warehouse managers know the importance of separating this salt from reactive chemicals or strong acids to prevent unwanted reactions.
MES Sodium Salt, with its distinct structure and widespread use, falls under international trade regulations with the HS Code 2921.49 for organic heterocyclic compounds. This code streamlines global shipments, keeps customs processes straightforward, and will show up on every invoice, bill of lading, and regulatory document moving the raw material across borders. This level of traceability supports transparency in laboratory supply chains and aligns with the regulatory principles of major markets like the EU, US, and China. The code helps lab managers and procurement teams order large volumes with confidence, knowing the product matches specifications and safety standards.
The raw materials behind MES Sodium Salt include high-purity morpholine, ethylene compounds, and sodium sulfite streams. The origins and purity of each matter, especially when contaminants sneak into the synthesis pipeline, affecting how the buffer performs. Quality control in the supply chain extends from screening these starting reagents to stepwise monitoring as the reaction flows to its endpoint. Top suppliers provide certificates of analysis, batch testing reports, and third-party verification. It all feeds into the reputation of MES Sodium Salt as a dependable buffer for irreplaceable research and sensitive manufacturing processes.
Beneath the white grains and the clear solutions sit hard facts of chemistry: MES Sodium Salt's density, at about 1.5 g/cm³, matters for shipping, storage, and lab work. Specific volume is the inverse: around 0.67 cm³/g. Every calculation, from stock solution mixing to bulk order handling, touches these numbers. Research teams need accurate molecular weight—217.24 g/mol—when measuring grams for a buffer at 1X or 10X strength. Errors in these calculations show up in wasted time, missed experiments, or, worst case, unreliable results in critical testing.
MES Sodium Salt supports breakthroughs in diagnostics, protein engineering, drug discovery, and industrial fermentation. Those small, nearly invisible crystals play an outsized role keeping reactions in the sweet spot. Consistency, batch-to-batch, gives confidence to workers mixing liters of stock solution, running large fermenters, or operating robotic drug screening labs. The properties of the salt make it straightforward to scale from benchtop beakers to 1,000-liter tanks. Reliability in physical form, purity, and documented safety underpins the entire chain of operations, from order to application.
Every person who’s spent hours in a lab or on a factory floor knows the mess a spilled container can cause. MES Sodium Salt calls for dry, sealed containers—no humidity, no open air, no light. Bags and jars go on shelves away from acids. Gloves stop the skin irritation, goggles fend off splashes. Accidental spills clean up with water and a vacuum, no harsh solvents required. Disposal goes by approved local rules, with waste streams often running through neutralization before sending to drains. Keeping the work area tidy, with routines for labeling and rotating stock, cuts errors and keeps labs safe.
MES Sodium Salt does not promise flash or excitement, but its physical properties—density, molecular weight, crystal structure, solubility in water—make it a staple in every lab where pH precision matters. Every container tells a story of supply chains, chemical engineering, and science in action. The commitment to purity, safety, traceability, and clear chemistry supports true progress, whether in the basement lab or global pharma plant.
