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HS Code |
451611 |
| Productname | Acetamidine Hydrochloride |
| Casnumber | 1668-25-7 |
| Molecularformula | C2H7N2•ClH |
| Molecularweight | 94.55 g/mol |
| Appearance | White to off-white crystalline powder |
| Meltingpoint | 164-168°C |
| Solubility | Soluble in water |
| Purity | Typically >98% |
| Storagetemperature | 2-8°C |
| Synonyms | Acetimidamide hydrochloride; Ethanamidine hydrochloride |
| Ecnumber | 216-788-1 |
| Phvalue | 4.5-6.5 (50 g/L, 20°C in water) |
As an accredited Acetamidine Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Acetamidine Hydrochloride is supplied in a 25g amber glass bottle, sealed with a screw cap, and labeled with product details and safety warnings. |
| Shipping | Acetamidine Hydrochloride is shipped in tightly sealed containers to prevent moisture absorption and contamination. Packages are clearly labeled with hazard and handling instructions. Transport follows local and international regulations for chemical substances, typically via ground or air freight, ensuring compatibility with other cargo and appropriate temperature control if needed. |
| Storage | Acetamidine Hydrochloride should be stored in a tightly closed container at room temperature, ideally between 2–8°C (36–46°F). It must be kept in a cool, dry, and well-ventilated area, away from direct sunlight, moisture, and incompatible substances. Proper labeling and secure storage help prevent contamination and accidental exposure. Avoid sources of ignition and strong acids or oxidizers. |
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Purity 99%: Acetamidine Hydrochloride with purity 99% is used in pharmaceutical synthesis, where it ensures high yield and minimal by-product formation. Melting Point 164°C: Acetamidine Hydrochloride with a melting point of 164°C is used in custom reagent development, where stable solid-state processing is required. Molecular Weight 94.53 g/mol: Acetamidine Hydrochloride with molecular weight 94.53 g/mol is used in heterocyclic compound synthesis, where precise stoichiometry improves reaction efficiency. Particle Size <100 μm: Acetamidine Hydrochloride with particle size below 100 μm is used in fine chemical reactions, where rapid dissolution enhances reagent availability. Stability Temperature up to 40°C: Acetamidine Hydrochloride with stability temperature up to 40°C is used in storage and transport applications, where product integrity is maintained over extended periods. Hydration Level Anhydrous: Acetamidine Hydrochloride (anhydrous) is used in moisture-sensitive synthesis processes, where unwanted hydrolysis reactions are minimized. pH Range 4.0–5.0 (1% solution): Acetamidine Hydrochloride with pH range 4.0–5.0 (1% solution) is used in buffer preparation for biochemical assays, where consistent assay conditions are critical. Solubility in Water 50 g/L: Acetamidine Hydrochloride with solubility in water of 50 g/L is used in aqueous reaction systems, where rapid dissolution accelerates process throughput. Assay (HPLC) ≥ 98%: Acetamidine Hydrochloride with assay (HPLC) ≥ 98% is used in analytical standard preparation, where accuracy and reproducibility are essential. Residual Solvents <0.1%: Acetamidine Hydrochloride with residual solvents below 0.1% is used in medicinal chemistry research, where high product purity reduces interference in bioactivity studies. |
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Acetamidine Hydrochloride shows up in the shelves of research labs and fine chemical warehouses for a good reason. Scientists and people working in pharmaceuticals rely on it for its straightforward chemical makeup and predictable performance in synthesis. The experience of working with it feels reliable—clean, white crystals, easy to weigh, and ready to dissolve in water. Graduate students and experienced chemists alike appreciate the ease with which this compound slips into reactions.
Unlike materials that require special storage or constant temperature monitoring, Acetamidine Hydrochloride carries a reputation for stability. Anyone who’s spent hours managing sensitive reagents knows that small conveniences like this matter. The product's chemical structure—an amidine flanked by a hydrochloride group—gives it properties that open doors in both organic and inorganic synthesis. It also outscores some competitors in terms of solubility and handling safety, making it a favorite in classrooms and small-scale industry labs.
Acetamidine Hydrochloride, with a CAS number of 1668-10-6, comes as a fine crystalline powder that flows easily. In the industry, its molecular formula, C2H7N3·HCl, gets cited because it serves as a shorthand for purity and expected behavior. The product usually arrives at a purity level exceeding 98%, which most labs find adequate for both preparation and analysis. This compound dissolves readily in water—no need for fiddling around with hotplates or sonicators. The melting point typically sits around 165-170°C, high enough to remain solid under ordinary storage, but not so high that it resists processing if any separation step is needed.
Packing comes in sealed plastic-lined containers, often around 100 grams to a kilogram per bottle, though bulk options exist for industry buyers. For the many involved in day-to-day quality control or routine chemical production, packaging design can affect workflow. Clear labeling and a well-designed cap save time and prevent cross-contamination. Even the texture—soft, non-hygroscopic, without clumps—forces a certain appreciation. Everyone who’s lost time scraping solidified powders from bottles knows how small details like these make a real difference on busy days.
Experimenting with Acetamidine Hydrochloride in the lab opens up access to a range of organic reactions—most notably, the synthesis of heterocyclic compounds. For teachers running undergraduate labs, it fits nicely with practical demonstrations of basic condensation and cyclization reactions. In pharmaceutical research, it takes on a heavier role. Medicinal chemists use this compound to build nucleic acid analogues and other drug candidates, tracing out molecular pathways that lead to new therapies. The intermediate steps it enables often determine whether a synthetic plan flies or falls flat.
This product also serves a purpose in dye and pigment manufacturing. Its straightforward reactivity makes it a stepping stone to more elaborate building blocks in color chemistry. For those who’ve mixed batches of high-performance dyes, choosing a reactant with low impurity levels matters. Here, Acetamidine Hydrochloride stands out compared to cheaper, less-controlled alternatives that can introduce variable performance. Those committed to reproducibility find that sticking with high-purity lots like these cuts down on failed reactions and surprise troubleshoot calls in the middle of a shift.
Some companies specializing in agricultural chemicals also pick Acetamidine Hydrochloride to create safe intermediates for pesticide development. Finding a feedstock that doesn’t complicate downstream purification lightens the regulatory load and helps the R&D team focus on innovation rather than cleaning up messes left by bad precursors. It’s easy to take for granted, but having a starting point every chemist recognizes saves both time and money in the bigger picture.
Getting the most out of Acetamidine Hydrochloride doesn’t mean it’s the best fit for every job. There are other amidines and hydrochloride salts out there—some geared toward extremes of reactivity, others toward cost savings on a huge scale. For large, low-spec manufacturing, less-refined versions of related chemicals offer economies that might seem hard to pass up. Yet those savings often come at the expense of reliability and ease of use.
Any chemist who’s tried to switch out Acetamidine Hydrochloride for a similar compound in a key reaction soon finds out that even small differences can derail an otherwise smooth process. Some related compounds split under heat or light, giving off unpleasant byproducts that can turn a white powder brown or yellow. Others barely dissolve, leaving stubborn slurries in reaction flasks and making product isolation a headache. Comparing batches from different suppliers can feel like rolling dice, especially when quality management standards slip.
Stable, high-grade Acetamidine Hydrochloride sticks to the basics: dissolving clean, weighing out easily, holding up in ambient conditions, and matching purity claims against certificates of analysis. People counting on repeatable results eventually settle on trusted sources, and in this market, that usually comes down to proven lots with a track record.
In laboratories, scientists look for more than just a chemical. They look for tools that reduce headaches, and Acetamidine Hydrochloride often fits that bill. Its shelf stability means managers don’t have to invest in special climate control. Lower tendency to hydrolyze removes one frequent cause of ruined samples. In a world of tightly managed budgets, these features save both time and money.
Pharmaceutical pilots benefit from it, too. Running a multi-step reaction sequence demands confidence in every ingredient. Swapping one suspect amidine for Acetamidine Hydrochloride can boost yields and cut troubleshooting. Reproducibility in medicinal chemistry is key to getting new candidates across the daunting “valley of death” between discovery and development. I’ve seen teams stuck for weeks on blocked synthesis open up that bottleneck just by switching in a better-built precursor like this one.
The focus on high-purity, single-lot production batches helps industries hit their regulatory marks. Traceability stands out as a silent asset when audits come around. Chemical stewardship doesn’t always grab the headlines, but compliance officers will always trade sleep for certainty each time a well-documented batch enters the workflow.
There is a certain temptation in the industry to cut corners by turning to lower-cost alternatives. It can seem on paper like a smart move—until something goes sideways. That’s happened the few times I’ve watched a team fight color drift in dye lots after switching from high-grade Acetamidine Hydrochloride to generic substitutes. Or in screening runs for agricultural products, where batch-to-batch inconsistency from a cheaper amidine hampered reproducibility across sites.
Veterans of the pharmaceutical industry have countless stories about projects coming off the rails because of low-purity starting materials. A little extra outlay for a solid product heads off expensive problems. Consistency saves more than just dollars. It builds trust across research teams, lab managers, and front-office auditors who have to defend every line item come budget review.
Labs that run method development or analytical validation often support dozens of projects at once, and the comfort of knowing that reagents like Acetamidine Hydrochloride come with documented analyses and transparent supply chains cannot be underestimated. In larger operations, this translates to smooth process validation, easier scale-up approvals, and fewer unplanned changes creeping into regulated filings. Those are not minor considerations once regulatory scrutiny comes into play.
The modern chemical and life sciences industries are more safety-conscious than ever. Many older chemicals in this category come with headaches—dangerous vapors, dust that irritates lungs, or byproducts that challenge waste disposal teams. Acetamidine Hydrochloride, in my experience, shows itself as a more manageable option. Fewer complaints roll in from the floor about odors or unexpected reactions, and that’s not something every compound can offer.
Today’s labs need more than theoretical safety; actual handling matters. The product's physical form means less airborne dust during weighing, and standard lab gloves handle the material without issue. Industrial hygienists will point out that these details matter over years, not just days. Ergonomics remain a silent partner to productivity, too—easier handling means fewer spills and less stress during training for new staff. Anyone who’s taught junior chemists remembers that small victories with new protocols can set the tone for months ahead.
The chemistry community, paying closer attention now to sustainable practices, has shown an interest in reducing waste and minimizing risk. Switching to reagents that require less stringent waste management (within local regulations) ticks both boxes. For the companies facing environmental audits or tight controls on chemical inventory, simplifying disposal—by choosing cleaner, less reactive feedstocks where possible—can slash hidden costs and future liabilities.
In research and manufacturing, the edge goes to the chemical that does its job without drawing attention. Acetamidine Hydrochloride fits that description. It lets researchers focus on the chemistry, rather than wrangling with impurities, variable hydration states, or surprise side reactions—all common headaches with less-trusted alternatives. In the race to new molecules or scaled-up production, these practical advantages matter more than a shiny spec sheet.
Pharmaceutical and biotech teams, under pressure to push projects forward, do not have the luxury of retooling entire synthetic pathways. Consistent, high-quality feedstocks reduce troubleshooting, accelerate method clearance, and deliver cleaner samples for biological screening. Graduate students, postdocs, and early-career chemists all recognize the difference when a reaction just works, letting them focus on the route ahead rather than fighting fires in the background.
For those in chemical manufacturing, shortening cycle times and reducing rejects sit firmly at the top of the wish list. That becomes possible when the core reagents behave exactly as promised. Experienced operators remember the pain of chasing down subtle batch-to-batch differences—yellowing, partial reactivity, or lingering contaminants that show up weeks later in product testing. The track record of Acetamidine Hydrochloride in quality-control labs holds up to scrutiny, making it a predictable staple for those looking to take human factors out of daily operations.
Although Acetamidine Hydrochloride already meets a high standard, the push to do better never stops. Suppliers working closely with their clients tend to offer enhanced quality documentation, more traceable supply chains, and options for even tighter impurity profiles. Chemists tasked with scaling up new syntheses also look for flexible packaging, more environmentally friendly containers, and transparent sourcing. These efforts might seem invisible to the casual buyer, but for people who manage regulatory filings or audits, every improvement counts.
Companies with bigger sustainability goals ask more from their chemical providers. Options for bulk purchasing, reduced shipping waste, and lifecycle analysis checks are increasingly common topics during supplier negotiations. Scientists who care about sourcing ethical feedstocks want documentation that backs up supply chain claims—not just a certificate of analysis, but details on origin, transit, and storage. It’s good to see the market adapt as buyers hold suppliers accountable for both environmental impact and product purity.
For those in academia, open communication about sourcing and certificate authenticity helps prevent wasted runs and supports reproducible science. If anything, the future of research-grade chemistry will hinge on better transparency from vendors and more dialog between end-users and suppliers. Trust sits at the core of every good experiment, and trust in reagents comes from shared knowledge and openness about what’s in the bottle.
The best insights into Acetamidine Hydrochloride come from the trenches. Colleagues who switched from lower-quality reagents to verified, high-purity lots saw measurable gains in process reliability and run-to-run consistency. Troubles that once slowed progress—persistent side products, unexpected color changes, or low yields—eased up after changing over to a reputable supplier’s product. These aren’t just anecdotes: they translate into real savings and smoother workflows, both in academic and industrial settings.
Young chemists learn early to separate product hype from results they can see, weigh, and measure. During group meetings, the difference boils down to less need for controls, sharper NMR spectra, and cleaner end products. In scale-up, managers breathe easier knowing a single container of Acetamidine Hydrochloride can serve as both a teaching tool and a production workhorse. That sort of flexibility keeps projects rolling along, bridging gaps between laboratory innovation and tangible output.
People sometimes take for granted the role that well-made, reliable reagents play in discovery. For every breakthrough drug, process improvement, or academic insight, there’s a story in the background about the ingredients that made it possible. Acetamidine Hydrochloride doesn’t always get top billing, but its reputation is built on solving real-world problems, making it a staple worth understanding, using, and improving.
Markets change and so does the chemistry landscape. The demand for higher standards means products like Acetamidine Hydrochloride have to keep up. Today’s clients want both immediate performance and the peace of mind that comes from quality assurance. It’s not just about brands or supplier history—value boils down to documented quality, clear sourcing, and a history of meeting performance claims. Labs juggling multiple projects and shifting timelines thrive by sticking with reagents that deliver exactly what’s expected.
There’s also more crossover now between traditional academic use and process-scale demand. Companies building new pharmaceutical libraries or branching into specialty dyes echo the needs of collegiate teaching labs: simplicity, reliability, and strong vendor support. Beginners benefit from straightforward materials that can handle a range of experiments, and professionals appreciate reduced noise in tricky syntheses.
With growing global supply networks and more pressure on chemical supply chains, quality control takes on a new urgency. Consistent sourcing and transparent materials tracking let buyers sleep easy, and in my conversations with industry veterans, real-world experience always trumps marketing claims.
The way forward for Acetamidine Hydrochloride and its users lies in continual collaboration. Open channels between chemists, manufacturers, and regulators mean improvements don’t stop at the factory door. Feedback loops—sharing observations about product handling, reporting issues, and requesting documentation—build a system in which everyone benefits. Equally, companies willing to invest in regular audits, hands-on QC programs, and staff training find themselves rewarded with smoother operations and fewer nasty surprises.
Today’s successful labs ask more of their suppliers: timely shipments, detailed batch records, and flexibility in order size to match research needs. That sort of dialog shapes the market and drives improvement industry-wide. As regulations tighten and expectations climb, the standout suppliers are those willing to be real partners, not just transaction points.
For chemists—students and professionals alike—Acetamidine Hydrochloride remains a practical, trustworthy choice. Its advantages go beyond the label: cleaner experiments, fewer failed runs, and a track record that supports continuous innovation. The effort to improve doesn’t end with the last bottle; instead, it encourages a culture where every player—from bench scientist to procurement lead—has a say in the quality of tomorrow’s chemistry.
