|
HS Code |
816888 |
| Chemical Name | 2-Pyridinealdoxime 1-methiodide |
| Cas Number | 3689-96-7 |
| Molecular Formula | C6H7N2OI |
| Molecular Weight | 266.04 g/mol |
| Appearance | White to light yellow powder |
| Melting Point | 190-194°C (dec.) |
| Solubility | Soluble in water |
| Smiles | C1=CC=NC(=C1)[N+](=C)O.[I-] |
| Storage Temperature | Store at 2-8°C |
| Synonyms | 2-Formylpyridine oxime methiodide |
| Pubchem Cid | 3064326 |
| Ec Number | 222-972-2 |
As an accredited 2-Pyridinealdoxime 1-methiodide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Pyridinealdoxime 1-methiodide is supplied in a 5g amber glass bottle with secure screw cap and detailed hazard labeling. |
| Container Loading (20′ FCL) | 20′ FCL: Securely packed drums or bags containing 2-Pyridinealdoxime 1-methiodide, properly sealed and labeled for safe chemical transport. |
| Shipping | 2-Pyridinealdoxime 1-methiodide is shipped in tightly sealed containers to prevent moisture and contamination. It is typically packed according to hazardous materials regulations, kept in a cool, dry place, and protected from light. Shipping documents include safety data sheets and proper labeling to ensure safe handling and compliance with transport regulations. |
| Storage | 2-Pyridinealdoxime 1-methiodide should be stored in a tightly sealed container, protected from light and moisture, and kept in a cool, dry, and well-ventilated area. The chemical should be kept away from incompatible substances, including strong oxidizers and acids. Follow local regulations and safety guidelines for chemical storage, and ensure access is limited to trained personnel. |
| Shelf Life | 2-Pyridinealdoxime 1-methiodide should be stored at 2-8°C, protected from light; shelf life is typically 2 years unopened. |
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Purity 98%: 2-Pyridinealdoxime 1-methiodide with purity 98% is used in pharmaceutical synthesis, where high purity ensures optimal yield and reduced by-product formation. Melting point 178°C: 2-Pyridinealdoxime 1-methiodide with a melting point of 178°C is used in analytical research, where thermal stability allows precise thermal analysis. Molecular weight 202.21 g/mol: 2-Pyridinealdoxime 1-methiodide with a molecular weight of 202.21 g/mol is used in drug discovery, where accurate molecular mass supports reliable compound formulation. Particle size < 10 µm: 2-Pyridinealdoxime 1-methiodide with particle size less than 10 µm is used in chromatography, where fine particle size leads to enhanced separation efficiency. Stability at 25°C: 2-Pyridinealdoxime 1-methiodide with stability at 25°C is used in laboratory storage, where ambient stability ensures consistent compound integrity. Solubility in water 25 mg/mL: 2-Pyridinealdoxime 1-methiodide with solubility in water of 25 mg/mL is used in biochemical assays, where high solubility enables accurate solution preparation. pH stability range 4-8: 2-Pyridinealdoxime 1-methiodide with pH stability range of 4-8 is used in buffer systems, where chemical stability maintains reliable assay conditions. Assay by HPLC > 98%: 2-Pyridinealdoxime 1-methiodide with assay by HPLC greater than 98% is used in quality control testing, where high assay value guarantees reproducibility of experimental results. |
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2-Pyridinealdoxime 1-methiodide stands out in the world of chemical reagents. Many researchers recognize it by its model number and formula, C7H9N3O, as a specialty compound focused on precise applications in pharmaceutical and chemical studies. Sourcing pure and reliable reagents can make or mar an experimental setup, especially when working with sensitive processes. From what I've seen in years of lab work, small variables in a compound’s quality ripple outward, creating bigger problems down the line. This product is popular because it brings consistency that researchers and manufacturers can lean on.
I’ve used my share of off-brand aldehydes and salts over the years, chasing budget options for tight projects, and noticed subtle yet critical differences in outcome. With 2-Pyridinealdoxime 1-methiodide, the reproducibility of results comes from stringent manufacturing and careful purification. Labs use this compound mainly for enzyme inhibition assays, medical research, and in the synthesis of specific intermediates. For example, in the study of acetylcholine esterase reactivators, particularly in antidote development, purity of each reagent becomes essential. A margin of error in this space doesn’t just waste time; it risks human lives when translated to medical use.
In many drug discovery workflows, scientists screen molecules that mimic or interfere with body chemistry. 2-Pyridinealdoxime 1-methiodide isn’t just another line in a catalog. Its quaternized nitrogen atom, locked in the cationic form, makes it particularly effective as a nucleophile. I’ve worked in a lab where quick access to stable, well-characterized oximes allowed us to test new ideas about poisoning antidotes without waiting weeks for a trusted supplier. In toxicology, especially where nerve agents are involved, any delay in sourcing reliable reactivators could cost institutions dearly.
Academic papers and technical documents show 2-Pyridinealdoxime 1-methiodide performing strongly in systems involving the reactivation of phosphorylated enzyme complexes. Oximes without the methylated nitrogen sometimes lag behind, unable to cross certain biological barriers or falling short in reaction kinetics. Field medics and pharma engineers have pressed for cleaner reagents because downstream processes depend on it. The wrong impurity profile means a batch of test drugs could fail stability trials, costing months.
Pharmaceutical manufacturing doesn’t just chase efficiency. It is about minimizing risks, especially those that can arise from one weak joint in a complex system. Researchers in neurology and emergency medicine rely on this product because it holds up to international standards for purity, batch consistency, and chemical identity. In regulatory environments, every lot comes tested for identity by spectral fingerprinting—think NMR and Mass Spec. Results line up within tight tolerances, giving teams confidence to push their work forward with reduced analytical guesswork.
2-Pyridinealdoxime 1-methiodide appears as a pale crystalline powder under room conditions, stable enough for regular lab routines but never something you’d treat casually. Every good kit labels its melting point between 180 and 183 °C, a tight range for quality assurance. In my own experience, running melting point checks becomes a routine first step—seeing it consistently pass that test signals well-controlled synthesis and purification on the manufacturer’s end.
Solubility matters. This compound dissolves readily in water, a trait that amplifies its appeal in biological assays and clinical research setups. It saves time—no waiting on suspended particles or worrying over uneven dosing in a high-throughput screen. Some analogues take longer to dissolve or come with lingering cloudiness in solution, which throws off titrations and bioassays. Reliable solubility here means more reliable workflow.
Storage requirements don’t raise eyebrows—room temperature in a dry container keeps the material stable, and standard laboratory safety protocols for handling quaternary ammonium salts apply. The chemical’s nature calls for basic precautions, same as any moderate-risk substance. In the labs where I trained new staff, making sure everyone followed the established labeling and documentation routine made more of a difference than any single aspect of the storage technique. Safety comes from culture as much as from chemical containers.
What does 2-Pyridinealdoxime 1-methiodide offer that similar chemicals don’t? The answer shows up in both the benchwork and the literature. Non-methylated analogues like 2-pyridinealdoxime itself have a narrower range of biological compatibility. Methylation of the nitrogen improves both charge stability and solubility, which is critical for biological reactivity. In studies on cholinesterase reactivation, the 1-methiodide variant shows superior potency and selectivity—qualities that cannot be matched by less sophisticated analogues.
Some alternative oximes come in less pure forms or rely on intermediary vendors with looser quality control. Behind the scenes, this turns up as unexpected peaks in chromatograms and unexplained byproducts in downstream chemistry. These differences drive experienced chemists toward well-established brands and products. I remember a run-in with a cheaper version from an unfamiliar source, noticing the sluggish response in cell-based assays—results didn’t match the controls, hinting at hidden issues with the reagent itself. Consistency, batch after batch, becomes a quiet pillar for any serious lab work, and 2-Pyridinealdoxime 1-methiodide delivers on that front.
In the last decade, I’ve watched both small startups and large pharmaceutical firms elevate their scrutiny over lab chemicals. Traceability and quality assurance aren’t just buzzwords—they influence outcomes from research notebooks to regulatory filings. Responsible suppliers run rigorous tests on each lot, publishing analysis data that researchers can trust. For 2-Pyridinealdoxime 1-methiodide, certificates of analysis don’t just get filed away; they’re reviewed, cross-checked, and often become part of the submission documents for regulatory review.
The global focus on reproducibility in science has changed lab culture. It’s not just about getting the next result faster. It’s about knowing the conditions and materials that led to that outcome, so anyone else can repeat it—students, collaborators, or regulatory auditors. The compounds that hold up to intense documentation requirements become favorites, because they pollute the experimental process less with uncertainty. This is where 2-Pyridinealdoxime 1-methiodide draws loyal users.
For institutions that work at the edge of innovation, from chemical defense agencies to biotechnology startups, time and budgets run tight. Unreliable reagents can derail schedules and burn through resources. In my years working alongside researchers trying to move discoveries from pilot phase to actual products, supply chain questions came up nearly every week. If even a single lot went off-spec, entire timelines would shift and leadership would have to answer uncomfortable questions from funders. A single trusted source for a key reagent, delivering predictable quality, can free up time for real troubleshooting—instead of chasing down suppliers or repeating failed experiments.
2-Pyridinealdoxime 1-methiodide’s documented stability and reliable results matter whether the end goal is a scientific publication, a new therapy, or industrial-scale production. In my own project history, the most rewarding days came up when I could focus on pushing boundaries, not fixing last week’s supply chain headaches. Real progress demands this kind of reliable baseline.
Wide adoption of high-quality chemical reagents often bumps into budget realities, especially at smaller research centers. Experience shows that investing in the best grade up front pays off, saving teams from costly repeats or failed scale-ups. While some look for deals in the short-run, the project costs long-term spiral when batches fail verification or deliver irreproducible data. From my own budgeting experience, every dollar spent on trustworthy chemicals brought two back in reduced troubleshooting.
Part of the solution lies in better vendor transparency. Suppliers who share thorough documentation, open up channels for post-sale verification, and respond quickly to queries help smooth the path for researchers everywhere. I’ve seen the benefit of keeping strong relationships with sales reps and technical liaisons—immediate answers about a batch’s analytical profile or shipping chain can save a lot of stress during critical stages of product development.
Another part involves training new lab staff on why these issues matter. When new hires see firsthand how much havoc one poor-quality chemical can unleash, they approach procurement with a sharper eye. Some labs even cross-train between procurement and technical teams, strengthening the feedback loop from the bench back to the order desk. Learning from each other, teams spot problems faster and prevent costly delays.
A lot of attention goes to new discoveries and breakthrough products, but the routine steps—checking certificates, running reference tests, fostering communications across teams—build the backbone for every scientific advance. Products like 2-Pyridinealdoxime 1-methiodide become unsung heroes in these workflows. In every successful experiment I look back on, the smoothest ones shared one thing: trusted baseline components. Scientists and technicians who take pride in their tools, demand evidence, and support one another through challenges make these advances possible.
Maintaining documentation takes time, but it pays back with every successful run. In regulated environments, every batch and data point needs to be accounted for—knowing that a chemical meets the latest standards for purity and traceability lets research teams focus on results, not bureaucracy. If the cost of reliable chemicals seems steep, the alternative—projects set back by weeks or months—can ruin entire grant cycles and disrupt critical product launches.
Along with regulatory trends, innovation is moving fast in both synthetic methods and analytical testing. Laboratories equipped with better tools, like high-field NMR and high-res mass spectrometry, now spot microscopic impurities previously missed. This creates new hurdles for chemical suppliers but also pushes the bar higher for everyone working in the field. As I’ve seen, institutions adopting the latest testing and setting tight incoming acceptance standards end up ahead of the curve. For compounds like 2-Pyridinealdoxime 1-methiodide, this means constant improvement and learning make their way into each new lot—even longstanding suppliers incorporate feedback and revise their processes.
Advocating for improvements in industry standards always felt like an uphill climb at first. Yet collaboration across universities, industry, and vendor partners turns incremental tweaks into industry improvements. As open data sharing and supply chain transparency get more common, researchers everywhere benefit. More accessible reference spectra, open batch histories, and clear lines of communication flatten the learning curve for new labs integrating these compounds.
There’s a growing push towards greener synthesis and more responsible sourcing in specialty chemicals. 2-Pyridinealdoxime 1-methiodide, with its relatively simple structure and clear utility, sits squarely within reach of newer, cleaner production methods. The trend towards minimizing waste solvents, improving worker safety, and reducing byproducts has already begun to touch this area of chemistry. Smaller batch sizes for rapid turnaround, as well as modular synthesis approaches, now provide broader flexibility to customized research needs.
Technology has brought down the cost and complexity of analyzing batch data and chemical identity. Portable analytical devices, cloud data platforms, and open-source databases now let labs of all sizes independently verify shipments and compare findings worldwide. For a specialty product like 2-Pyridinealdoxime 1-methiodide, the accessibility to real-world data means less reliance on third-party assurances and more empowerment on the ground. I’ve witnessed labs in less-connected regions leapfrog traditional hurdles by sharing data with collaborators thousands of miles away, closing gaps that once seemed insurmountable.
It will be interesting to watch how continued advances in chemical engineering and supply chain logistics affect compounds with wide research and emergency medicine relevance. There’s enormous value in keeping a tight feedback loop between bench scientists, production chemists, and the sales or technical teams supporting them. As more chemicals approach commoditized consistency, the standouts won’t just be those with the lowest price tag, but those offering real transparency, batch reliability, and technical guidance at each stage of the research or production journey.
Nothing compares to the relief of spotting a familiar, trusted chemical in the stockroom when a project deadline looms. I remember the sense of security knowing that tomorrow’s experiments could start without a scramble for alternative reagents or backup plans. Every researcher has war stories about trying to “make do” in the face of late shipments or questionable purity—most of these result in extra work, disappointment, and more paperwork than progress.
People outside the lab often miss how much hidden work keeps big discoveries on track. Dozens of small, technical decisions add up each week. The presence of standard, well-characterized chemicals cuts through this noise, giving skilled teams a little breathing room to focus creativity and problem-solving on the hard parts of their work, not on adjusting for weak links in basic materials. This mental freedom spurs innovation and results that carry through from the lab bench to clinics and factories.
Reliable performance, open data, and teamwork shape the foundation for any successful research journey. With 2-Pyridinealdoxime 1-methiodide, the chemistry community finds a tool that balances tight quality controls and broad applicability in diverse scientific challenges. The story goes deeper than purity specs or catalog listings—the collective experience of hundreds of researchers, safety officers, and analytical chemists builds the strength behind a product’s reputation. Every careful decision, from raw material sourcing to documentation procedures, steers a product away from mediocrity and towards trusted mainstay status in laboratories around the world.
The character of a research reagent springs from the sum of its technical reliability and the culture of trust surrounding its use. Day by day, batch by batch, chemicals like 2-Pyridinealdoxime 1-methiodide help teams move forward, sidestepping distractions caused by uncertainty. As open standards, fair pricing, and cooperative relationships keep gaining ground, the broader scientific field stands to benefit from better results, safer workspaces, and breakthroughs that change lives.
