© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
728879 |
| Chemical Name | N-Methylmethoxyamine Hydrochloride |
| Cas Number | 6638-79-5 |
| Molecular Formula | C2H8ClNO |
| Molecular Weight | 97.55 g/mol |
| Appearance | White to off-white crystalline powder |
| Solubility | Soluble in water |
| Melting Point | 140-142°C (decomposes) |
| Storage Conditions | Store at 2-8°C, keep container tightly closed |
| Synonyms | N-Methoxy-N-methylamine hydrochloride |
| Purity | Typically ≥98% |
| Hazard Classification | Irritant |
| Inchi Key | LOIGFGBUXDLFGK-UHFFFAOYSA-N |
| Usage | Organic synthesis intermediate |
As an accredited N-Methylmethoxyamine Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 25g N-Methylmethoxyamine Hydrochloride comes in a sealed amber glass bottle with a tight screw cap and clear hazard labeling. |
| Shipping | N-Methylmethoxyamine Hydrochloride is shipped in tightly sealed containers, protected from moisture and light. It is typically dispatched as a solid, labeled in accordance with local chemical safety regulations. Proper cushioning prevents breakage, and documentation includes safety data. Shipping complies with relevant hazardous material transport guidelines to ensure safe handling and delivery. |
| Storage | N-Methylmethoxyamine Hydrochloride should be stored in a tightly sealed container, protected from light and moisture. Keep it in a cool, dry, well-ventilated area, ideally at 2–8°C (refrigerated). Store away from incompatible substances such as strong oxidizers and acids. Ensure the storage area is appropriately labeled and restrict access to trained personnel to maintain safety and chemical stability. |
|
Purity 98%: N-Methylmethoxyamine Hydrochloride with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product consistency. Melting Point 163-167°C: N-Methylmethoxyamine Hydrochloride with melting point 163-167°C is used in analytical reagent preparation, where it provides controlled thermal stability during analysis. Moisture Content <0.5%: N-Methylmethoxyamine Hydrochloride with moisture content below 0.5% is used in peptide coupling reactions, where it prevents unwanted hydrolysis and side reactions. Molecular Weight 95.55 g/mol: N-Methylmethoxyamine Hydrochloride with molecular weight 95.55 g/mol is used in metabolic labeling studies, where it enables precise quantification and tracking of molecular transformations. Stability Temperature up to 60°C: N-Methylmethoxyamine Hydrochloride stable up to 60°C is used in storage and handling within laboratory environments, where it maintains chemical integrity and reduces degradation risk. Particle Size <100 mesh: N-Methylmethoxyamine Hydrochloride with particle size less than 100 mesh is used in solid-phase organic synthesis, where it enhances solubility and reaction kinetics. Heavy Metal Content <10 ppm: N-Methylmethoxyamine Hydrochloride with heavy metal content below 10 ppm is used in diagnostic reagent formulation, where it ensures low toxicity and compliance with regulatory standards. Water Solubility >50 mg/mL: N-Methylmethoxyamine Hydrochloride with water solubility greater than 50 mg/mL is used in aqueous chemical derivatization protocols, where it allows efficient dissolution and homogeneous reaction conditions. |
Competitive N-Methylmethoxyamine Hydrochloride prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
Every so often, a chemical draws attention thanks to how smoothly it can fit into real research settings. N-Methylmethoxyamine Hydrochloride—sometimes seen on labels as N-Methylmethoxyamine HCl—has landed on lab benches across the world for a reason. Researchers and lab technicians steer toward this white crystalline solid because of its defined structure and solid physical properties, making it a dependable choice across different fields, especially in organic synthesis and pharmaceutical research.
The molecule isn’t flashy—it’s practical. This hydrochloride salt form of N-Methylmethoxyamine holds steady because of its chemical stability, shown in its moisture tolerance and resistance to slow decomposition. Typical lots offer high purity levels, often above 98%, and come in granular or fine-powder form. Chemists count on its batch-to-batch consistency and ease of measurement. Reliable supply sources ensure that the compound remains a standard part of the synthetic toolkit.
Its molecular formula makes a difference: with a methyl group attached to the nitrogen and a methoxy group on the chain, N-Methylmethoxyamine Hydrochloride stands apart from simple alkoxyamines. This adjustment in the molecule brings reactivity as well as selectivity. I’ve seen it picked time and time again during reactions where a chemoselective approach is necessary—a chemical’s quirks can make or break a multi-step procedure, so the structure truly matters.
Organic chemistry always looks for ways to gently coax one compound into another, with as few side reactions as possible. N-Methylmethoxyamine Hydrochloride quickly proved itself in this role. During my early days in a university lab, even some old-school advisors gave a nod to this compound for its reliability in the synthesis of oximes and hydrazones. Many of those reactions used to rely on less stable or more hazardous reagents. This hydrochloride salt version offers safer handling and easier weighing—a small but meaningful improvement over free bases that tend to absorb water or even degrade upon standing.
Outside pure chemistry, pharmaceutical labs use this compound as an intermediate or derivatization agent. Whenever a complex molecular scaffold needs a stable functional group, N-Methylmethoxyamine Hydrochloride often answers the call. Its selective reactivity means fewer surprises during the reaction, and its salt form dissolves nicely in a range of common lab solvents, giving flexibility for reaction conditions.
Many might look at N-Methylmethoxyamine Hydrochloride and question how it really differs from more familiar compounds like methoxyamine hydrochloride or N,N-dimethylhydroxylamine. From my time in both academic and pharmaceutical settings, subtle changes in molecule structure end up saving hours—sometimes days—during challenging syntheses.
Take methoxyamine hydrochloride, for example. While it remains a staple for introducing methoxyamino groups, its increased reactivity compared to the N-methyl variant can prove tricky, particularly when dealing with sensitive aldehydes or ketones. N-Methylmethoxyamine Hydrochloride faces fewer side reactions and delivers higher yields under mild conditions. In a field where time and reproducibility often dictate the pace of progress, that difference holds real value.
I’ve also watched N-Methylmethoxyamine Hydrochloride play a crucial role in medicinal chemistry. Researchers often need derivatives that offer both structural flexibility and optimized pharmacological profiles. The methyl substitution slightly alters both lipophilicity and metabolic stability, which can help in lead optimization and ADME profiling. For med chemists, small tweaks in starting materials sometimes lead to major improvements in potency, selectivity, or absorption—and this compound gives them a practical avenue for those tweaks.
Safe handling always sits at the center of any functional lab. The hydrochloride salt is less volatile and less prone to combustion concerns than its free base analogs. That means it finds a place on the open shelf in busy synthesis suites and isn’t confined to special cabinets except in high-volume or long-term storage cases.
Some years ago, a colleague pointed out that by shifting to hydrochloride forms, we saw fewer accidental spills and easier inventory control, especially during late-night reaction setups. While gloves and fume hoods remain non-negotiable, the peace of mind that comes with less hazardous reagents cannot be overstated. This compound checks that box for researchers who value safety but refuse to compromise on performance.
Innovation in life sciences, like drug development or new material design, hinges on reliable and efficient building blocks. Universities and startups both look for cost-effective ways to push projects forward. In my own work helping students design new small molecules and functionalized polymers, N-Methylmethoxyamine Hydrochloride showed up again and again. Its presence in the toolkit meant less troubleshooting after seemingly minor changes to a synthetic plan.
Many commercial suppliers offer this compound in various pack sizes, letting researchers balance cost and waste. I’ve noticed even labs operating on a shoestring budget manage to keep a small reserve of this compound, both for planned reactions and unforeseen challenges. It serves as a reminder that the best tools don’t always come from novel, cutting-edge design; sometimes, success follows simplicity and reliable performance.
Ask any seasoned organic chemist about recurring lab headaches, and you’ll probably hear tales of inconsistent reactivity, hard-to-control side products, and compounds that won’t dissolve or store well. N-Methylmethoxyamine Hydrochloride addresses several of those pain points. For one, the salt’s physical properties mean easier weighing and transfer, even in humid environments. No more clumped vials or wasted time scraping sticky materials from boats and spatulas.
Reactions that suffer from incomplete conversion or excessive byproducts benefit from this hydrochloride. In my experience, switching even a single step to N-Methylmethoxyamine Hydrochloride often streamlined purification. Chromatography columns ran cleaner, and reaction mixtures looked less murky. That improves not just convenience but also the longevity of lab equipment—filters and LC columns live longer when fed with purer mixtures.
The broader research community continues to share evidence that this compound offers more than a simple tweak in reactivity. Published literature points to cleaner conversion rates during carbonyl functionalization, higher selectivity with sensitive substrates, and better scalability for process chemists working in the pharmaceutical sector. A number of peer-reviewed papers support its use in combinatorial chemistry, where reliability across dozens of parallel reactions saves both costs and headaches for screening campaigns.
Behind the science sits something more: shared experience from countless trial runs, failed experiments, and incremental victories. I’ve lost count of the number of researchers who cite N-Methylmethoxyamine Hydrochloride as a quiet hero in their projects. It doesn’t bring the excitement of a blockbuster reagent, yet it consistently enables complex transformations that more temperamental chemicals might stall or sabotage. In group meetings and coffee-room chats, stories tend to focus on how a “small switch” like moving to this compound made a tough transformation work, or cut a week’s worth of troubleshooting from an already crammed project timeline.
With research fields always pushing toward new frontiers, every dependable reagent extends its value. For machine-assisted synthesis and flow chemistry platforms, N-Methylmethoxyamine Hydrochloride earns trust. Its solid format and solubility profile prove helpful, and suppliers have responded by ensuring consistent quality control for automated labs and scaled production.
Analytical labs—particularly those involved in bioanalytical and environmental monitoring—have also found the compound useful for derivatization steps that increase detection sensitivity and enable quantification at low concentrations. Efforts toward developing newer pharmaceuticals that require specific functionalization of intermediates keep the demand steady.
Nothing in synthetic chemistry is without challenge. While the hydrochloride salt solves many problems, disposal practices and environmental stewardship still matter. Waste streams containing organic amines and hydrochlorides must be treated to avoid introducing persistent contaminants. Some labs have begun to develop more efficient neutralization systems, targeting both safety and sustainability. I’ve worked as part of teams exploring solvent recovery and assessing green chemistry alternatives; integrating these steps into research routines sharpens both compliance and environmental responsibility.
Purchasing teams should keep a close eye on supply chain traceability and quality certification, especially in growing sectors where production standards may fluctuate. While major suppliers deliver robust documentation, smaller sources sometimes struggle to meet these benchmarks. The community can address this by fostering open communication among labs, advocating for transparent sourcing, and sharing performance feedback—whether positive or cautionary. As a result, users across academia and industry continue to raise standards for purity and quality, benefiting everyone downstream.
Science moves with both tradition and innovation. Compounds like N-Methylmethoxyamine Hydrochloride inhabit a middle ground—simple, not experimental, but skilled in what they do. Newcomers to the lab see it as a proven resource, while older hands recognize it as a dependable choice that frees their attention for true experimentation.
Commercial research and discovery programs value time savings and reproducibility, outcomes that reinforce ongoing trust in this compound. Each year, as synthetic strategies get more complex and timelines more pressing, researchers return to the familiar utility of compounds that “just work.” N-Methylmethoxyamine Hydrochloride doesn’t compete for the spotlight and doesn’t promise miracles; instead, it delivers consistent results and peace of mind.
Teaching young scientists has always involved more than equations and reaction mechanisms. Experience teaches that small choices, like using a more stable form of an amine, prevent frustration and build confidence. Across campuses and research centers, mentors help students understand the not-so-obvious advantages—such as the storage stability or safer handling of a hydrochloride salt over a free base.
I’ve watched students shoulder assignments with tight deadlines and unpredictable resources. Being able to trust the quality and performance of key reagents, like N-Methylmethoxyamine Hydrochloride, can make all the difference. Not every lesson comes from flashy breakthroughs; sometimes, the most valuable knowledge grows from using the right tool for the job.
Peer-reviewed research and published case studies say one thing, but daily lab life often teaches other lessons. In group meetings, the quiet satisfaction of a successful synthesis using N-Methylmethoxyamine Hydrochloride always sparks discussion. From joining collaborative grant projects to helping commercial partners fix a stalled drug development program, the consistent results—cleaner reactions, smoother purifications, reliable storage—stand out in shared lab experience.
As the number of applications grows, the community finds more creative uses for established compounds. N-Methylmethoxyamine Hydrochloride plays roles in fields outside its original scope, tackling new protocols or acting as a stepping stone to next-generation materials. My own projects have turned to this compound for unexpected solutions, whether simplifying a difficult route or correcting a late-stage functionalization. Such experiences reinforce an important truth in chemistry: reliable building blocks enable bold thinking, while unreliable ones limit possibilities before the work even begins.
N-Methylmethoxyamine Hydrochloride keeps proving itself as a key player in research labs. It stands out because it balances reliability, safety, and targeted reactivity, making life easier for students, academic researchers, and professional chemists alike. Its unique chemical structure serves as the backbone for both routine and advanced syntheses, while its physical properties and safety advantages support better research outcomes. The lasting value of this compound comes not from marketing, but from experience, community trust, and a steady track record of making hard chemistry a little easier.
