|
HS Code |
952704 |
| Iupac Name | pyridine-3-carboximidamide |
| Molecular Formula | C6H7N3 |
| Molar Mass | 121.14 g/mol |
| Cas Number | 521-55-9 |
| Appearance | White to off-white solid |
| Melting Point | 193-197 °C |
| Solubility In Water | Soluble |
| Pubchem Cid | 10759 |
As an accredited pyridine-3-carboximidamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle labeled "Pyridine-3-carboximidamide, 25g." Features hazard warnings, batch number, expiry date, and tightly sealed cap. |
| Container Loading (20′ FCL) | **Container Loading (20′ FCL):** Pyridine-3-carboximidamide is securely packed in 25 kg fiber drums, totaling up to 8–10 metric tons per 20′ FCL. |
| Shipping | Pyridine-3-carboximidamide should be shipped in tightly sealed containers, protected from moisture and incompatible substances. It must be clearly labeled and handled according to standard chemical shipping regulations. The package should be cushioned to prevent breakage and typically transported at ambient temperature unless otherwise specified by safety data guidelines. |
| Storage | **Pyridine-3-carboximidamide** should be stored in a tightly closed container, in a cool, dry, and well-ventilated area. Keep it away from sources of ignition, heat, and incompatible substances such as strong oxidizers. Protect from moisture and direct sunlight. Store in accordance with local regulations and ensure proper labeling to avoid accidental misuse. |
| Shelf Life | Shelf life of pyridine-3-carboximidamide is typically 2–3 years when stored in a cool, dry place, tightly sealed. |
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Purity 98%: pyridine-3-carboximidamide of 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal impurity formation. Melting point 156°C: pyridine-3-carboximidamide with a melting point of 156°C is used in organic synthesis, where it provides reliable solid-state stability during storage and processing. Molecular weight 136.15 g/mol: pyridine-3-carboximidamide at 136.15 g/mol is used in medicinal chemistry applications, where it enables precise dosage formulation and prediction of pharmacokinetic properties. Particle size <50 µm: pyridine-3-carboximidamide with particle size less than 50 µm is used in catalyst preparation processes, where it offers enhanced surface area for improved reaction rates. Stability temperature up to 120°C: pyridine-3-carboximidamide stable up to 120°C is used in thermal processing steps, where it maintains chemical integrity without degradation. Solubility in DMSO 50 mg/mL: pyridine-3-carboximidamide soluble at 50 mg/mL in DMSO is used in biological assay development, where it enables efficient stock solution preparation for consistent experimental results. |
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Pyridine-3-carboximidamide may not sound familiar unless you spend your days working with organic synthesis or diving deep into pharmaceutical research. The compound often serves as a sturdy building block for more complex molecules, showing up across laboratories where innovation is the goal. While chemical names sometimes seem intimidating, they actually mark important steps in drug discovery and material science. This substance brings specific advantages, especially when researchers look for a molecule with defined reactivity and stability. What’s striking about pyridine-3-carboximidamide is how it supports the development of important medicines and agricultural chemicals without stumbling over common pitfalls seen with less pure or less stable alternatives.
Coming across this compound in a laboratory is not an everyday affair, at least outside of industrial research or specialized chemistry programs. Yet, its rise in prominence is no accident. Over the past decade, demand for effectual intermediate compounds has put unique molecules like pyridine-3-carboximidamide on the radar of research chemists who want a competitive edge. This isn’t just another reagent to toss into the mix — its structure, a pyridine ring bonded with a carboximidamide group at the third position, unlocks routes to synthesize biologically active agents and crop-protection formulas.
In my academic years, I saw students and professionals alike wrestle with finding the right ingredient for constructing nitrogens into aromatic systems or supporting catalytic reactions. Early on, I noticed that some people overlook specific molecular traits in favor of “whatever is available,” but this shortcut often leads to frustration. Pyridine-3-carboximidamide, with its reliable reactivity and manageable safety profile, stands apart. Even in small-scale experiments, it demonstrated a knack for serving as a precursor for guanidine derivatives, often yielding products that avoided unwanted side reactions.
Once you take a closer look at this compound’s specifications, the reasons it stands out become clearer. Pyridine-3-carboximidamide comes as a solid, usually with a pale color. In hands-on work, the most important features fall into the purity range and the consistency of batch quality. Highly purified versions, achieved using crystallization and modern purification techniques, help researchers avoid time-consuming troubleshooting down the line. Many vendors offer products with purity well above 97%, matching the standards expected in pharmaceutical and academic labs.
The molecular structure isn’t complex for a trained eye, but it brings distinct benefits. The pyridine core sets the stage for aromaticity, which translates to chemical stability and a solid foundation for further modification. Then comes the carboximidamide group, which introduces an avenue for both nucleophilic and electrophilic chemistry, making this molecule a flexible intermediary. I recall working with alternatives that either lacked sufficient solubility or gave unpredictable yields. Pyridine-3-carboximidamide usually dissolves in common solvents like water, DMSO, or ethanol and maintains performance in both mild and harsh reaction conditions.
Handling this material doesn’t present undue challenges for professionals. With safety gear and the usual lab ventilation, standard protocols keep risks manageable. It’s rare to encounter dramatic side effects from contact or exposure compared to more hazardous reagents; this makes classroom demonstrations and training exercises much less stressful, a real win for educators and junior chemists. Despite this, users always owe respect to any lab chemical, and attention to published material safety guidance pays dividends.
Pyridine-3-carboximidamide shines brightest where specificity and yield matter most. Researchers often lean on it during steps where introducing or protecting nitrogen groups on aromatic rings is the central challenge. In pharmaceutical research, for example, the molecule helps unlock new candidates for antiviral or anticancer drugs, where its nitrogen atom can act as a reliable attachment site for further reactions. I’ve spoken with colleagues who shared stories of long experiments derailed by unstable intermediates, and in those situations, switching to pyridine-3-carboximidamide sometimes helped turn failure into progress.
Beyond the bench, agricultural scientists find value in its predictability during the synthesis of plant protection agents. More specifically, the compound sometimes serves as a core structure for developing new herbicides or growth regulators. Here, being able to count on a reproducible chemical foundation gives innovators time to focus on refining properties, not struggling with inconsistency. Every season, the ability to translate milligram-scale synthesis from the lab to pilot plant production often spells the difference between a promising candidate and a commercial flop. Pyridine-3-carboximidamide, by pulling its weight in this crucial development stage, offers a measure of reliability.
During a period in which I collaborated with a team reinventing synthetic pathways for guanidine drugs, this compound proved crucial. We needed a scaffold that wouldn’t break down or participate in side reactions under mild heating. Repeated attempts with aldehyde-based alternatives led us down dead ends, either through low yields or the formation of impurities that complicated purification. In contrast, using pyridine-3-carboximidamide provided consistency and clarity, allowing the team to scale processes without surprises lurking from batch to batch. That kind of steadiness seems almost undervalued until you’re working under tight deadlines in a project-packed environment.
Anyone comparing this molecule to other candidates quickly notices where it differs. While some may point to more common alternatives like benzamidine or simple imidamide derivatives, pyridine-3-carboximidamide presents both structural and functional advantages. Its aromatic ring, featuring a nitrogen, gives it increased stability under many synthetic conditions. Some organic bases or guanidine precursors prove difficult to handle due to poor solubility, sensitivity to moisture, or instability in air. Having worked with a range of similar compounds, I found a clear reduction in headaches using this one — less time spent chasing down lost product, more time progressing science.
Consider also the environmental and economic angles. Laboratories and pilot plants look for compounds that neither explode budgets nor create waste headaches. Pyridine-3-carboximidamide fits well here compared to several related guanidine sources, reflecting a midpoint between affordability and high-end performance. The synthesis recipes I’ve seen also adopt safer reagent choices, reducing hazards for operators and downstream waste handlers alike. Clean reactions, with minimized by-product output, don't always excite headlines, but they fuel real change across the chemical sector.
In my experience, older compounds with similar functional groups sometimes required excessive purification steps, and their shelf lives disappointed. Opening a bottle of degraded material after six weeks on the shelf can wreck planned experiments for the week or month. The current industry push for rationalized, predictable chemical suppliers means that reliable shelf stability and clear supplier documentation bring peace of mind. Pyridine-3-carboximidamide, with consistent supply and robust shelf life in proper storage, reduces unpleasant surprises. That reliability means cost savings and more usable research hours, factors every program manager appreciates.
Choosing what seems like a minor component at the planning stage of a complex project sometimes has ripple effects well beyond the laboratory walls. High-purity intermediates, such as pyridine-3-carboximidamide, quietly enable breakthroughs in active pharmaceutical ingredients. I remember a time working on a painkiller project, and an off-the-shelf chemical repeatedly tripped up our analytical screens with impurities. We learned quickly to source cleaner, traceable intermediates, and ever since, choosing the right product up front became less an afterthought and more an integral part of process design.
The same story plays out in agricultural innovation. With each growing season bringing new climate swings and regulatory updates, formulation experts count on dependable building blocks to keep research on target. If a key component shifts in quality or chemistry — no matter how subtle the change — the field outcomes can swing unpredictably, costing time, resources, and trust with business partners. By anchoring development projects around a proven intermediate like pyridine-3-carboximidamide, researchers and production managers create a buffer against avoidable setbacks.
Taking a big-picture view, it makes sense to consider the downstream impacts. Supply chain issues sometimes disrupt projects, especially when critical chemicals only come from single regions or require fragile distribution routes. In more recent years, the supply of pyridine-3-carboximidamide has diversified, with improvements in both manufacturing capacity and global distribution. As someone who watched delays ripple through a multinational drug project over a missing reagent, I have come to appreciate how resilient supply chains free up energy for solving actual science, not just logistics.
These days, scientific integrity starts long before the experiment kicks off. Researchers and companies need trusted sources, clear documentation, and transparent quality assurance. Pyridine-3-carboximidamide stands out in part because credible providers support their materials with full certificates of analysis, stability testing, and access to technical service. I remember years ago, tracking uncertainty about a different product, where the lack of clear documentation put experiments at risk. By contrast, reliable sourcing for this compound means peace of mind for everyone from bench chemists to quality auditors.
Regulatory compliance is not optional, especially when the end uses target regulated markets like pharmaceuticals or food crops. Responsible suppliers meet these requirements, offering documentation to support everything from purity confirmation to safe transport. This isn’t wasted effort or bureaucracy for its own sake; it forms the baseline trust that lets researchers build new therapies or assurance for food supply without worrying over hidden surprises. Most successful labs now treat supplier vetting with as much rigor as internal quality checks, strengthening the partnership between research and procurement.
What often gets overlooked is the time saved during troubleshooting or root-cause analysis when issues arise. High-quality pyridine-3-carboximidamide, with clearly traceable certificate data, speeds up diagnosis. With one less variable to worry about, teams work more efficiently, and science progresses with fewer bottlenecks. This kind of traceability and supplier transparency dovetails with the global emphasis on research integrity and reproducibility — an issue that continues to make headlines well beyond just chemistry circles.
Any mention of chemicals in today’s market raises fair questions about safety and environmental impact. As regulatory landscapes change and businesses aim for sustainability milestones, chemicals like pyridine-3-carboximidamide must meet higher expectations. Professional chemists and environmental officers alike check for comprehensive safety data, environmental fate, and end-of-life considerations. During a project focused on green chemistry, the discussions always circled back to finding intermediates that allowed promising transformations while keeping accident, exposure, and disposal risks low.
Solutions spring from a proactive approach. Rather than waiting for regulations to force change, more producers and users of these specialized compounds embrace improvements in purity, minimized hazardous reagents, and closed-loop processing. Pyridine-3-carboximidamide benefits from synthesis protocols that prioritize safer reagents and include robust end-of-pipeline controls. In more advanced settings, waste stream capture and recycling further reduce the compound’s long-term environmental impact.
It’s easy to forget that every large-scale product in medicine or agriculture once began as a small-scale experiment fueled by curiosity and careful planning. The unsung heroes were often the intermediates smartly chosen by those with the patience to benchmark products and the courage to avoid shortcuts. Pyridine-3-carboximidamide, with its mix of chemical reliability, user safety, and strong technical documentation, represents a practical midpoint between cost, compliance, and scientific promise.
What does the future hold for researchers and innovators who rely on intermediates like pyridine-3-carboximidamide? Judging by the pace of change, ongoing development in reaction engineering, catalysis, and material science will continue pushing this molecule into new corners of research. Every time a new process requires a stable, modifiable core structure — whether for medical breakthroughs, environmentally friendly pesticides, or next-generation materials — it’s likely that compounds of this class will get a hard look.
On multiple occasions, I’ve heard project leads celebrate when a reliable intermediate shaved weeks off development timelines, freeing up bench time and budget for more exploratory work. Having stable, high-quality chemicals available without the need for repeated adjustments expands creative freedom in the lab. That’s true from graduate research all the way to global product development. Reliable access to advanced intermediates also supports new educational models, where students can focus on learning synthetic skill and technique instead of firefighting unreliable components.
Existing suppliers appear to understand the value of ongoing support, rolling out batch-tracked documentation, lot-to-lot consistency, and responsive customer service. These measures reflect an industry that now expects and rewards accountability. For every research leader balancing costs against technical requirements, the message from users is clear: transparent, quality-first chemical supply increases both productivity and discovery.
Ultimately, progress in applied chemistry depends not just on major breakthroughs, but on a continuous chain of choices that move science forward step by careful step. The growing reputation of pyridine-3-carboximidamide isn’t due to a media spotlight, but to quietly consistent performance across varied applications. From its clear documentation and stable supply to its strong performance in both pharmaceuticals and agriculture, the story of this compound is a reminder that responsible sourcing and smart technical choices still drive real value.
My experience reinforces a broader truth: investing in proven intermediates with full transparency and traceability delivers long-term payoffs. Not every project turns into a blockbuster, but every step forward builds on a foundation of careful, informed choices. As regulatory, supply chain, and technical landscapes grow increasingly complex, products like pyridine-3-carboximidamide, which consistently deliver on quality, safety, and performance, offer a sense of certainty that keeps both everyday research and major innovation moving.
