N-(Carbamoylmethyl)Taurine stands out as a versatile compound, popular in both laboratory research and some specialty industry applications. This molecule contains taurine linked through a carbamoylmethyl group, which gives it a blend of unique attributes that mean more than just chemical interest. People who work in chemistry or materials science will often spot this name in projects focused on enhancing solubility, finding more stable intermediates, or tweaking the properties of consumer and industrial materials. The raw material falls into a class of mild surfactant-type amino acid derivatives and rarely remains unmentioned in projects needing reliable interaction with both organic and inorganic materials.
Looking at the structure, N-(Carbamoylmethyl)Taurine comes from taurine—a naturally occurring sulfonic acid—modified on its amine nitrogen with a carbamoylmethyl chain. Its molecular formula reads C5H12N2O4S, which breaks down to carbon, hydrogen, nitrogen, oxygen, and sulfur atoms in a specific balance. Each atom in the makeup anchors particular functional areas: a sulfonic acid group on one side, an amide in the linker, and a methyl group providing some modularity for reaction chemistry. The molar mass hovers near 212.23 g/mol, which makes accurate weighing and mixing straightforward for technical staff using even standard laboratory balances.
The product never arrives as one, uniform shape. Purified N-(Carbamoylmethyl)Taurine will often look like white flakes, a crystalline powder, or solid pearls, depending on who manufactures or purifies it and how much care goes into solvent removal. Sometimes advanced suppliers provide this compound as a clear or slightly cloudy solution, generally water-based, for folks who plan on direct dosing or liquid-phase processing. Each shipment receives a batch-specific assay, water content, and substantial purity documentation—frequently complimented by chromatograms and spectral analysis for picky researchers. Physically, the density falls in a range near 1.35–1.40 g/cm³ when dry and compacted, giving a reasonably accurate basis for packing, transfer, or bulk estimation. For those dealing with raw logistics, understanding the substance’s shipping code—HS Code 2924199090—simplifies customs, taxation, and compliance, since it falls under organic chemicals not elsewhere specified.
N-(Carbamoylmethyl)Taurine demonstrates strong hydrophilicity, likely because of both its sulfonic acid and amide groups. This allows it to dissolve easily in water, forming clear to slightly opalescent solutions at concentrations up to 10–15% by mass. In solid form, the product resists air-oxidation and rarely discolors, a plus for storage and shelf life. In most cases, the relatively neutral pH of dissolved samples means minimal interaction with glassware, plastics, or most metals used in reactors. Teams evaluating this compound for raw material sourcing appreciate the predictability—N-(Carbamoylmethyl)Taurine won’t surprise you with unpredictable reactivity, as long as you keep it away from strong oxidizers or acids. Staff handling hazards note that, like most low-molecular-weight amino-derivatives, this compound carries slight irritation risks, especially if inhaled as dust or handled over bare skin for long periods. Safety data often assign it a ‘handle with standard precautions’ label – gloves, ventilation, and eye protection carried over from general laboratory or production SOPs.
Any downstream or application-focused team will notice that the physical form strongly shapes how easy dosing or blending becomes. Flaked or powdered samples disperse with standard mixers, but pearls or pre-made liquid formulations help when dust control or precision dosing gets critical. Each form has a place, depending on the specific factory or research setting. Crystalline quality can occasionally determine suitability for high-purity research or materials production stages. Granular size and free-flowing behavior can keep production lines running smoothly—an insight often overlooked during procurement.
N-(Carbamoylmethyl)Taurine does not fall onto major hazardous chemical control lists, although thorough review of its toxicity data surfaces mostly mild local effects from direct exposure or repeated contact. It makes sense to treat all chemical powders with respect, but existing evidence places it in a group with considerably lower risks than many alternative sulfonic or amino acid derivatives. People working in chemical handling should take seriously any long-term or large-volume exposure—keeping a close eye on air quality, dust control, and good cleanup routines. Environmental discharge mostly boils down to controlled wastewater handling, since the substance remains water-soluble and does not accumulate in soils or fatty tissues. Storage guidance tells users to keep containers fully sealed, labeled, and clear of any reactive or strongly oxidizing agents; products left open can gradually absorb water and become sticky, changing not just ease of handling but also final product consistency for customers further down the supply chain.
Chemists and product engineers continue to explore new uses for N-(Carbamoylmethyl)Taurine, with growing interest in fields like polymer modification, detergent formulation, and biochemical intermediates. The ability to tailor surface charge, adjust solution behavior, or link bio-relevant chemical motifs means this compound punches above its weight in formulation science. Current research includes studies on micelle formation, metal chelation, and ways to stabilize sensitive actives in finished goods. Teams designing safer, more functional consumer products often turn to this molecule as either an additive or a linker between other key components. From a supply perspective, reliable purity and physical consistency remain top concerns. Suppliers who guarantee solid documentation, batch tracking, and fair testing regimes often find recurring audience among technical users.
The people using N-(Carbamoylmethyl)Taurine seldom want surprises, either in the lab or on the factory floor. Material buyers and process managers ask pointed questions about particle size, residual solvents, flowability, and cross-contamination risk. Because regulations keep tightening—especially across markets like Europe, Japan, or North America—up-to-date safety data, compliance records, and third-party analytical certifications build trust. Technical documents pass from procurement through quality assurance onto bench scientists, each role knowing they depend on the predictability and integrity of the product sent out in each drum or pack. For anyone tasked with reshaping sourcing or process steps around N-(Carbamoylmethyl)Taurine, learning the subtle differences between grades, forms, and specifications can mean the difference between smooth production cycles or costly reworks due to unexpected lot variability.
