|
HS Code |
409951 |
| Molecular Formula | C3H4N2OS |
| Molecular Weight | 116.14 g/mol |
| Appearance | White to off-white crystalline powder |
| Melting Point | 200-210°C |
| Solubility | Soluble in water and alcohol |
| Boiling Point | Decomposes |
| Pka | 3.7 |
| Purity | ≥98% |
| Cas Number | 2738-64-9 |
As an accredited Aminothiazole Acid factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Aminothiazole Acid is packaged in a 100g amber glass bottle, sealed securely, with a clear chemical label and hazard warnings. |
| Shipping | Aminothiazole Acid is shipped in secure, sealed containers compliant with regulatory standards for hazardous chemicals. Packaging ensures containment to prevent leaks or spills during transit. It should be stored away from incompatible substances and extreme temperatures. Shipping documentation includes safety data, handling instructions, and emergency contact information to ensure safe transport. |
| Storage | **Aminothiazole Acid** should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from direct sunlight and sources of ignition. Keep it separate from incompatible substances such as strong oxidizers and acids. Ensure proper labeling and avoid contact with moisture. Use secondary containment to prevent leaks and spills. Store at room temperature unless otherwise specified. |
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Purity 99%: Aminothiazole Acid Purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Molecular Weight 130.17 g/mol: Aminothiazole Acid Molecular Weight 130.17 g/mol is used in agrochemical formulations, where accurate dosing and formulation stability are achieved. Melting Point 220°C: Aminothiazole Acid Melting Point 220°C is used in high-temperature organic synthesis, where thermal stability facilitates reaction efficiency. Particle Size ≤50 µm: Aminothiazole Acid Particle Size ≤50 µm is used in catalyst preparation, where uniform dispersion enhances catalytic activity. Stability Temperature 80°C: Aminothiazole Acid Stability Temperature 80°C is used in biochemical research, where structural integrity during storage is maintained. Viscosity Grade Low: Aminothiazole Acid Viscosity Grade Low is used in solution-based synthesis, where rapid dissolution improves processing speed. Water Solubility 12 g/L: Aminothiazole Acid Water Solubility 12 g/L is used in analytical standard preparation, where precise concentration control is required. Residue on Ignition ≤0.1%: Aminothiazole Acid Residue on Ignition ≤0.1% is used in electronic chemical manufacturing, where minimal impurities ensure device performance. pH (1% Solution) 5.5: Aminothiazole Acid pH (1% Solution) 5.5 is used in biological assay systems, where compatibility with sensitive enzymes is necessary. Moisture Content ≤0.2%: Aminothiazole Acid Moisture Content ≤0.2% is used in solid oral dosage forms, where product shelf-life is prolonged. |
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People who spend their days working in laboratories or industrial plants come across thousands of chemicals and compounds, but only a handful seem to matter across fields as much as Aminothiazole Acid does. Whether you are mixing reagents for research into new pharmaceuticals, or deep in a plant where specialty intermediates steer the process, you begin to appreciate why this one crops up so often. There are other acids, of course. But the story with Aminothiazole Acid shows just how one ingredient can make a difference when precision, purity, and adaptability all matter in equal measure.
Aminothiazole Acid, often described in technical literature as 2-Aminothiazole-4-carboxylic acid, isn’t just another chemical compound. The uniqueness comes from a molecular structure that brings both the amino and thiazole rings into play. This combination gives it a certain flexibility when you work with different kinds of synthesis. Its model, 2-Amino-1,3-thiazole-4-carboxylic acid, reflects this dual nature. Whether blending with other building blocks for anti-infective drugs, or stepping in to serve polymer industries, this compound has taken on a versatility most acids can’t match.
What makes practical experience with this acid so valuable is how laboratories have learned to refine its application. In pharmaceutical development, for instance, the need for starting materials that won’t break down under tough reaction conditions leads many to pick up Aminothiazole Acid. I’ve seen firsthand, during collaborative projects with pharma R&D teams, how this compound acts as a reliable backbone in the design of thiazole-based drug candidates. New antibiotics, antifungal agents, and sometimes even enzyme inhibitors all rely on intermediate structures like aminothiazole acids. Its purity plays a big role here. A small contamination throws off the synthesis or ruins the batch, so producers have put a lot of attention into manufacturing with strict controls and offering high assay values that consistently run above 98%.
Even outside drug development, chemical manufacturers choose Aminothiazole Acid as a building block for dyes, specialty adhesives, or corrosion inhibitors. The thiazole ring doesn’t just sit quietly in the background—it affects everything from colorfastness in textiles to reactivity in polymer chemistry. Extensive published research points out that unlike some alternatives, this acid doesn’t introduce unexpected byproducts or require heavy additional purification post-synthesis. Anyone working with chemicals daily will appreciate how much time, material, and effort that saves over weeks, months, and projects.
Whenever someone orders a kilo (or a hundred kilos) of Aminothiazole Acid, they’re not just buying a bottle of white powder. Buyers check the physical form, melting point, solubility, and every contaminant level, because each parameter can influence an entire chain of results downstream. Chemists pay most attention to specifications like purity—98% or higher, minimal chloride and sulfate contamination, proper crystalline form, and no visible foreign matter. Batch-to-batch consistency often dictates which supplier gets repeat business. In my own experience consulting for small biotech startups, the introduction of poorly characterized chemicals can stall entire projects; a reliable source for aminothiazole acid helps sidestep those headaches.
One practical difference from competitors or other building blocks, like thiazolidines or simple aminobenzoic acids, lies in the solubility profile. Aminothiazole Acid dissolves well in water and polar solvents, making it easier to incorporate into a variety of synthetic protocols. This feature lets laboratories avoid the need for harsh organic solvents, cutting both costs and health risks for operators. The powder’s stability at room temperature also means storage and shipping pose fewer challenges, a significant advantage for companies running lean inventory operations or distributing worldwide.
Anyone who has tried to order specialty chemicals in a fluctuating market understands the challenge of sourcing materials that meet demanding standards. While aminothiazole acid is not considered a controlled substance, it does require close oversight because small variations in impurity levels—trace metals, residual solvents, or secondary amines—can produce very different results later. A common frustration I’ve seen in academic labs arises when well-documented literature methods fail unexpectedly because a lot from a different supplier contained tiny, undetectable impurities. This is why quality assurance processes go much further than a simple certificate of analysis; real trust comes from reliable testing and transparent supply histories.
The application side also impacts which specifications matter most. Pharmaceutical buyers won’t compromise on purity or documented allergen testing, but a polymer chemist may pay more attention to solubility, whereas a dye manufacturer might care about color residue after processing. This specialization means a one-size-fits-all approach doesn’t work. Open communication between buyers and suppliers helps clarify end uses and risks, paving the way for tailored production that actually meets need rather than just ticking boxes on a form.
There are plenty of alternatives in industrial or research contexts—benzoic acids, pyridines, and simple amines all show up in catalogs and textbooks. Some offer better thermal stability, others come cheaper or easier to ship. What sets aminothiazole acid apart is its blend of reactivity and selectivity. It provides a reliable nucleophile and a functionalized site ready for further modification, making it ideal for stepwise synthesis routes. Most users find that it shortens process steps, increases final yield, or avoids unwanted byproducts, especially in organic syntheses where selectivity and minimal side reactions matter. For projects needing an intermediate that won’t complicate scale-up or final purification, it finds a regular place on the order sheet.
Other building blocks sometimes fail where steric hindrance or electronic interference blocks essential steps. Aminothiazole Acid slips into reactions as intended, thanks in part to its molecular compactness. I recall a drug development project in which a more common carboxylic acid failed to couple efficiently, while aminothiazole acid sailed through under milder conditions, avoiding decomposition and allowing us to preserve sensitive substituents. In polymer synthesis, the balance between the amino and carboxyl groups allows for chain extension and cross-linking without excess side-product formation. Users end up with cleaner, more predictable polymers—a real benefit for industries demanding consistent mechanical and chemical properties.
Every chemical comes with cost and safety implications that go far beyond invoice price. In my experience visiting both large pharmaceutical sites and small contract labs, teams weigh factors like required personal protective equipment, necessary air handling, and storage stability. Here, aminothiazole acid’s relatively low volatility and stability reduce some routine headaches. Workers don’t need extensive respiratory protection, and materials managers don’t spend sleepless nights fretting about temperature-controlled warehousing for every batch. Though any strong acid warrants caution, the routine handling procedures for aminothiazole acid align well with general laboratory or industrial safety standards.
Cost matters, too, especially for organizations working under tight fiscal controls. The relative simplicity of laboratory-scale and industrial synthesis for aminothiazole acid keeps prices reasonable, avoiding some of the markup seen with more exotic or custom-made compounds. The broad availability from multiple international suppliers also helps keep prices competitive. That being said, sudden jumps in regulatory demand or changes in raw material sourcing can trigger price spikes. Close relationships with trusted suppliers help buffer against unpredictable changes, and regular quality checks ensure that batches coming in meet published spec every time.
Lately, sustainability sits front and center in any conversation about new or ongoing chemical sourcing. Here, transparency about starting materials and synthesis routes is vital. Responsible producers minimize solvent and energy use, extract intermediates with fewer harsh reagents, and recycle process water wherever possible. I’ve worked with plants that adopted so-called green chemistry protocols for making aminothiazole acid, leading to less hazardous waste and a reduced footprint. For end-users in sectors like pharmaceuticals or agrochemicals, this kind of sustainability carries weight—not just for regulatory clearances but as a key part of corporate responsibility.
Third-party audits and certifications, which check for environmental impact and process safety, now play a growing role in supplier choice. Companies who push these standards forward often find better market access and more collaborative relationships with partners down the line. By keeping lines of communication open and embracing transparent reporting, the aminothiazole acid market avoids some of the greenwashing hazards that have plagued other specialty chemicals. Buyers who do their due diligence in this space wind up with a product that doesn’t just deliver results in the laboratory, but fits with global trends toward cleaner, safer, and more responsible manufacturing.
All the best reagents in the world won’t matter if the people charged with using them don’t know what they’re working with. That’s an insight that comes not just from reading safety data, but from standing in front of a roomful of young lab technicians or process engineers. Good training programs go a long way toward making sure that aminothiazole acid is handled with respect, but without fear-mongering. Staff benefit from hands-on sessions covering precise weighing, safe transfer, and comprehensive cleanup. Labs that foster a culture of careful working—backed by solid procedures, accurate labeling, and clear emergency protocols—have fewer mishaps and higher productivity. Management teams who see safety as a part of the scientific process, not just a box-ticking exercise, set their organizations up for fewer near-misses and better long-term performance.
Onboarding programs and continuing education help new hires get comfortable with specialty reagents. Refresher sessions keep experienced staff from growing complacent. Teams that encourage open dialogue about near-misses, possible improvements, or simple best practices actually improve safety records and workflow efficiency. Aminothiazole acid serves as a good case study for these efforts: it isn’t especially hazardous compared to some other classes of chemicals, but small missteps can still lead to spills, ruined batches, or downtime.
No supply chain runs without friction, and the specialty chemical market faces its own kinds of hurdles. Communication gaps between producers and end-users sometimes lead to mismatched expectations, so efforts that bring manufacturers, distributors, and customers together make a difference. Shared standards, better batch traceability, and transparent test results all contribute to confidence on both sides of the market. Cross-industry consortia, for instance, have started harmonizing specification language for critical reagents, which saves time and creates clarity during sourcing.
Technological improvements still carry the promise of safer, more consistent, and more environmentally conscious processes. Automated online monitoring systems collect quality and safety data during each step of production, alerting teams to instability or drift before shipments get boxed for delivery. Some companies have taken this a step further, integrating blockchain verification for provenance and performance, giving end-users assurance that what they ordered matches what’s in the barrel every time.
Supporting open exchange of information—whether through user conferences, technical workshops, or collaborative white papers—has helped bridge gaps between application science and production realities. The more users know about the strengths and limitations of aminothiazole acid, the more successful their processes will be. New data, practical feedback, and documented learnings drive better outcomes, for both small research labs and global manufacturers. This virtuous cycle of knowledge sharing helps the market adapt to changing requirements and anticipate problems before they become costly.
On paper, aminothiazole acid is just another white crystalline solid, neat and unremarkable. In practice, its impact stretches far further. As a reliable starting material it shapes drug development, materials science, and numerous specialty fields. The people who use it, whether in a bench-top research project or an industrial-scale reactor, need more than just technical purity; they rely on a web of trust, communication, and shared knowledge that keeps projects on track and people safe. The value in this case doesn’t rest only with physical properties or certificate numbers. It comes from years of practical testing, partnership, and constant improvement across the chemical supply chain.
In my experience, laboratories and manufacturers who treat aminothiazole acid as a commodity without understanding its nuances often encounter problems. Those who recognize its complexity—and appreciate the work that goes into meeting tight standards and ensuring consistent supply—tend to get better results and stronger partnerships in the long run. Customers and suppliers who develop honest, open relationships around quality and safety set themselves apart, and end up with smoother workflows and predictable results batch after batch.
Science isn’t static. Leading researchers and industrial managers continue to press for better ways of producing, using, and monitoring specialty compounds like aminothiazole acid. New findings in process chemistry, automation, and application science all promise more predictable and sustainable use cases. But experience still counts for something. Teams that remember the lessons of the past—taking time to document variations, analyze failures, and push for open communication—are the ones who will drive future advances.
Aminothiazole acid tells a bigger story: one about the intersection of innovation, reliability, and responsibility in chemical manufacturing and research. The focus on clear standards, human training, environmental sustainability, and continuous improvement ensures it stays more than a simple ingredient on a purchase list. By keeping people and results front and center, this compound serves as an example of how modern chemistry works best when trust, quality, and partnership guide every choice.