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HS Code |
852556 |
| Product Name | 3-IODO-2-METHOXYPYRIDINE |
| Purity | 99% |
| Cas Number | 112898-00-7 |
| Molecular Formula | C6H6INO |
| Molecular Weight | 235.03 g/mol |
| Appearance | Light yellow to yellow liquid |
| Boiling Point | 274.0 °C at 760 mmHg |
| Density | 1.804 g/cm3 |
| Refractive Index | 1.617 |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Smiles | COC1=NC=CC(=C1)I |
| Inchi | InChI=1S/C6H6INO/c1-9-6-5(8)3-2-4-7-6/h2-4H,1H3 |
| Flash Point | 120.5 °C |
As an accredited 3-IODO-2-METHOXYPYRIDINE 99% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 10 grams; labeled “3-IODO-2-METHOXYPYRIDINE 99%,” with hazard symbols and lot number clearly displayed. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packs 3-IODO-2-METHOXYPYRIDINE 99% in sealed drums/cartons, maximizing space and ensuring safe, compliant transport. |
| Shipping | 3-Iodo-2-methoxypyridine 99% is shipped in sealed, chemically resistant containers, protected from moisture and light. It is classified as a hazardous material and must be handled according to relevant safety regulations, including appropriate labeling and documentation. Shipping requires compliance with international transport guidelines for chemicals to ensure safety and regulatory adherence. |
| Storage | Store 3-Iodo-2-methoxypyridine (99%) in a tightly sealed container, away from light, moisture, and incompatible substances such as strong oxidizers. Keep in a cool, dry, well-ventilated area, ideally under inert atmosphere if possible. Store at room temperature or as specified by the supplier, and ensure proper labeling and secondary containment to avoid accidental spills or exposure. |
| Shelf Life | Shelf life of 3-IODO-2-METHOXYPYRIDINE 99% is typically 2-3 years when stored in a cool, dry, and dark place. |
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Purity 99%: 3-IODO-2-METHOXYPYRIDINE 99% with high purity is used in pharmaceutical intermediate synthesis, where it ensures minimal impurity formation and optimal yield. Melting Point Range 55-58°C: 3-IODO-2-METHOXYPYRIDINE 99% within a defined melting point range is used in solid-state organic reactions, where consistent phase behavior enhances reaction reproducibility. High Chemical Stability: 3-IODO-2-METHOXYPYRIDINE 99% with high chemical stability is used in storage and handling for chemical manufacturing, where prolonged shelf life and batch reliability are maintained. Low Moisture Content: 3-IODO-2-METHOXYPYRIDINE 99% featuring low moisture content is used in anhydrous reaction conditions, where it prevents hydrolysis and side product formation. Defined Particle Size: 3-IODO-2-METHOXYPYRIDINE 99% with controlled particle size is used in automated reagent dispensers, where uniform dosing efficiency is achieved. Analytical Grade: 3-IODO-2-METHOXYPYRIDINE 99% at analytical grade is used in chromatography method development, where it enhances the accuracy and precision of quantitative analysis. Batch-to-Batch Consistency: 3-IODO-2-METHOXYPYRIDINE 99% with verified batch-to-batch consistency is used in regulated research environments, where it facilitates reproducible experimental outcomes. |
Competitive 3-IODO-2-METHOXYPYRIDINE 99% prices that fit your budget—flexible terms and customized quotes for every order.
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In the world of organic chemistry, researchers constantly look for ways to streamline the process of building complex molecules. Experience has taught me that even small improvements in starting materials can save hours in the lab, not to mention the costs of unnecessary troubleshooting. 3-IODO-2-METHOXYPYRIDINE 99% fills a gap for those working with pyridine-based scaffolds, especially where high purity and reliable substitution patterns matter.
This compound, featuring an iodine atom at the 3-position and a methoxy group at the 2-position of the pyridine ring, stands out among substituted pyridines. Its structure makes it more than another halogenated heterocycle. The dense electron cloud around iodine encourages smooth cross-coupling reactions. Decades in academic labs and contract research organizations have revealed one simple fact: reproducible yields rely on reagent quality, especially when setting up palladium-catalyzed couplings or direct arylations. This 99% purity material leaves behind nagging doubts about contamination or low-grade starting points, providing confidence to postdoctoral chemists and industry professionals who cannot afford failed batches or wasted solvent.
3-IODO-2-METHOXYPYRIDINE works well as an intermediate for synthesizing pharmaceuticals, particularly where selective functionalization on the pyridine ring brings out activity in target compounds. Medicinal chemistry teams prize such molecules for their ability to serve as flexible handles. The presence of the methoxy group can control the electronic character of the ring, making further transformations more predictable—a lesson that often emerges after a few ruined flasks when trying to substitute less forgiving compounds.
Colleagues in chemical manufacturing agree that inconsistency in starting material always leads to problems downstream. It’s not just about producing a few milligrams for publication anymore. With the rise of high-throughput synthesis and scale-up studies, reproducibility matters more than ever. If you run twenty reactions in parallel, variance in reagent quality multiplies headache and cost. Over years of troubleshooting failed Suzuki reactions, it becomes clear that lower-grade iodopyridines often carry unknown contaminants or moisture—both of which kill yields and clog up columns in purification.
By insisting on material with a minimum 99% purity, chemists manage risk better. Analytical chemists have shown again and again that batches below this threshold invite surprises. For those working on regulatory submissions, such as new molecular entities or active pharmaceutical ingredients, impurities from poor starting reagents land right in the final impurity profile. Documentation gets harder, rework soars, and opportunities slip away to more careful competitors. I’ve witnessed projects burn through their timelines fixing mistakes from shoddy starting compounds—a costly and avoidable error.
Pyridine rings show up everywhere, from antifungals to kinase inhibitors. The trick is to modify them while keeping everything else in the molecule safe. Historical synthesis routes to decorated pyridines involved lots of protection-deprotection steps and unwieldy workups. 3-IODO-2-METHOXYPYRIDINE 99% simplifies things. The heavy iodine atom acts as a favored leaving group in palladium-mediated couplings, outclassing chlorinated or brominated analogues for challenging C–C bond formations. Over the years, I’ve found that using iodo-substituted pyridines routinely cuts down on time wasted extracting products from stubborn tar or reconstructing reaction conditions from scratch.
Even research students new to the bench see the difference. The methoxy group at the 2-position is more than decorative. It tunes the electronics of the pyridine, making selective transformations far easier. This is especially useful for researchers building libraries of bioactive compounds, where precision in each modification means better screening hits and, ultimately, a faster path to discovery. Those frustrated by inconsistent reactivity from off-the-shelf halopyridines know how much more reliable results feel with well-characterized inputs. After mentoring generations of chemists, I can say there are few substitutes for starting with the right tool.
Some chemists might not pay much attention to small details like lot-to-lot consistency. The more time you spend scaling up reactions or teaching new workers, the more you notice the cost of shortcuts. I recall nights spent in the lab, sifting through NMR spectra trying to figure out why a reaction stalled, only to realize the reason traced back to an impurity introduced early on. High-purity reagents like 3-IODO-2-METHOXYPYRIDINE 99% significantly lower those risks. Industry case studies present the same message—reworking batches due to starting material problems drains resources much faster than investing upfront in better chemicals.
Modern procurement teams look at more than price tags. Total lifecycle costs, including time spent fixing problems, plant downtime, and quality assurance expenses, often dwarf marginal savings from cheaper but lower-purity options. Several major pharmaceutical manufacturers publish analyses showing that overall productivity and lower rejection rates follow directly from investing in pure reagents from trusted suppliers. Once damaged, project timelines rarely recover, especially in regulatory environments where every batch record gets combed over by auditors. In my experience, clean, traceable 3-IODO-2-METHOXYPYRIDINE brings tangible peace of mind—an asset valued by team leaders, QA officers, and impatient managers alike.
Anyone who spent years hunting for the right halogenated pyridine knows not all products deliver equal value. The position of the iodine and methoxy group on the ring changes everything about reactivity. For instance, 4-iodo or 2-iodopyridines lack the same selectivity and often behave more erratically under reaction conditions. Some other substituted pyridines tempt with lower sticker prices but rarely pass the tests of rigorous process optimization. Those working with alternatives often report reduced yields or byproducts creeping into final isolation stages. In practice, 3-IODO-2-METHOXYPYRIDINE 99% sets itself apart by providing both predictable reactivity and cleaner downstream processing. NMR and HPLC data show a sharp reduction in unwanted side reactions, which anyone racing through SAR studies can appreciate.
There’s also the matter of handling and safety. Lower-quality materials may carry noxious or unstable byproducts. Even a trace of excess oxidant, leftover acid, or residual solvent can scramble sensitive transformations downstream. I’ve cracked more than one flask due to runaway side reactions started by mystery impurities. High-purity offerings like this one show consistency in weight, color, and odor—simple clues that help identify quality at a glance, a lesson usually learned after a few unhappy surprises with questionable suppliers.
Drug discovery teams and process chemists share some common pain points: changing regulatory demands, complex impurity profiles, and increasingly tight timelines. Getting the right starting material, and getting it quickly, supports both model system studies and large-scale campaigns. When working on new modalities—whether old-school small molecules or hybrid frameworks—being able to trust every bottleneck step becomes more important. Years spent shepherding projects from hit to candidate status demonstrate that the fewer surprises from input materials, the easier it becomes to document robustness for downstream partners or regulatory filings.
Labs investing in high-throughput or automated platforms also lean heavily on reagent quality. Automation amplifies inconsistencies, turning small purity issues into big headaches. 3-IODO-2-METHOXYPYRIDINE 99% responds well to these environments because it reliably dissolves and reacts within well-established parameters. Machine-aided synthesis works best when every feedstock behaves as predicted; this material’s track record under pressure saves time and prevents cycle delays throughout the synthesis chain.
Years of bench and plant experience underline a simple truth—starting material quality shapes every downstream decision. If you ask development chemists what made a difference in their most successful projects, consistent input materials always make the list. The lessons stick with you after too many late night recovery runs or scrambled meetings to justify unexpected impurity spikes. 3-IODO-2-METHOXYPYRIDINE 99% has found its way into many successful projects, not simply because of its structure, but because of the credibility that comes from robust supply chains and regulatory support.
Suppliers who care about quality routinely back up their products with transparent batch histories, testing results, and traceable documentation. Projects involving this compound run smoother compared to those fueled by less carefully vetted alternatives. For companies operating in multiple regions or under different compliance regimes, that sort of predictability brings freedom to operate and confidence to manage risk. These intangibles are often more valuable than marginal cost savings, especially in settings where a failed batch can set back programs by months or even years.
Streamlined workflows benefit not just the bottom line but also sustainability efforts. Using high-purity 3-IODO-2-METHOXYPYRIDINE means fewer side products and less need for repeated purification. Academic and industrial labs both report less hazardous waste generated per gram of isolated product compared to lower-purity materials. Every reduction in extraction, column purification, or rework translates into less solvent burned and lower environmental impact—a goal that aligns with increasing corporate and public scrutiny on chemical practices. Process chemists talk about "greener" methodologies today, but those often start with good raw materials, not just clever engineering.
Efficiency gains build on each other. Teams putting together new synthetic routes often need to compare literature yields to their own results. Achieving results that match or beat published benchmarks gives a strong confidence boost—as well as support for patent claims or follow-on studies. In my experience, such reproducibility depends heavily on the purity and identity of each input; using 3-IODO-2-METHOXYPYRIDINE 99% bridges the gap between theory and practice.
No chemical product is without its complications. Concerns about scalable supply, global shipping delays, or changing regulatory interpretations affect the best-laid plans. But a close relationship with reputable suppliers of 3-IODO-2-METHOXYPYRIDINE 99% makes it easier to anticipate and address those bumps in the road. Experienced procurement managers know how vital it is to maintain open dialogue with supply partners, sharing upcoming needs and checking on upcoming regulatory shifts. For example, recent changes in import documentation practices in some regions forced adjustments on the fly—but teams with advance notice stayed on track, instead of scrambling for alternatives at the last minute.
Stability and labeling practices also vary between sources. Over the years, I’ve learned to scrutinize every new bottle that comes through the door. Small details like batch numbers, storage instructions, and accompanying spectral data sheets separate companies who take pride in their work from those cutting corners. When I share findings with colleagues or train new scientists, I always point out that success starts with the smallest habits—asking for recent analytical data and logging that information for all high-value reagents, especially those you rely on daily.
Behind every successful synthetic campaign stands a team of dedicated researchers, analysts, and support staff. Integrating high-purity 3-IODO-2-METHOXYPYRIDINE into lab routines brings both technical benefits and cultural ones. Newcomers learn the value of starting right. Experienced hands appreciate skipping the cycle of reaction troubleshooting and unplanned curveballs. Even grant reviewers and funding committees take notice when projects consistently deliver on time and within scope—a testament to discipline and best practices learned through countless trial runs.
Many organizations hold internal workshops or share case studies highlighting the impact of reagent quality on outcomes. Sharing such narratives within the chemical community helps solidify a culture of excellence. I’ve seen first-hand how shifting to high-purity, reputable sources sets a higher baseline for project ambitions. In time, those advantages ripple outward—reducing training time, increasing morale, and strengthening a spirit of collaboration among disparate teams, from discovery to development and QA.
The chemistry field never stands still. Whether mapping new reaction pathways or exploring uncharted drug targets, flexibility remains crucial. 3-IODO-2-METHOXYPYRIDINE 99% gives innovators a dependable foundation—a solid starting point from which to challenge conventions and build bold new molecular structures. This compound’s usability across diverse chemistry disciplines, including material science and agrochemical development, further underscores its importance. Every breakthrough in these areas rests on the quiet reliability of components chosen with care.
As green chemistry principles gain traction, and as automated research gains momentum, choosing the right inputs improves everything downstream. High-quality pyridines with clear chemical pedigrees allow scientists to focus on the challenging and creative work, rather than fixing avoidable errors. That creates more space for curiosity-driven inquiry and opens up possibilities for discovery beyond the horizon of current knowledge.
Anyone running syntheses involving substituted pyridines should consider the bigger picture. Cutting corners on input quality brings hidden costs, delays, and uncertainty. 3-IODO-2-METHOXYPYRIDINE 99% stands out from less pure or differently substituted alternatives because it consistently enables clean, reproducible chemistry. Professionals looking to accelerate their chemistry, meet regulatory requirements, and improve sustainability stand to gain the most from investing in high-quality inputs.
Building relationships with trusted suppliers, requesting current analytical data, and adopting a culture of traceability pay enduring dividends in project speed and final compound purity. Labs—whether academic or industrial—find more value in spending for reliability than in saving pennies up front. Lessons from long experience and the latest industry trends point toward high-purity reagents like this as critical contributors to success in research and production settings alike.
