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HS Code |
236221 |
| Iupac Name | 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine |
| Molecular Formula | C15H13N5O2S |
| Molecular Weight | 327.36 g/mol |
| Appearance | Solid |
| Cas Number | Unavailable |
| Structural Class | Triazole derivative |
| Functional Groups | Triazole, pyridine, nitro, thioether, methyl |
| Smiles | Cc1nnc(n1c2cccnc2)SCc3ccc(cc3)[N+](=O)[O-] |
| Inchi | InChI=1S/C15H13N5O2S/c1-10-19-18-15(20-21,14(17-10)13-6-2-4-8-16-13)23-9-11-3-5-12(7-11)22(21)22/h2-8H,9H2,1H3 |
As an accredited 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed in a 10-gram amber glass bottle with a tamper-evident cap, labeled with chemical name, purity, and hazard information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) involves securely packing 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine in sealed, labeled drums or bags. |
| Shipping | The chemical **3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine** will be shipped in tightly sealed containers, compliant with local and international regulations. Packaging will ensure protection from moisture, light, and physical damage. Transport will follow appropriate safety guidelines, including labeling for laboratory use and hazard classification if applicable. |
| Storage | Store **3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine** in a tightly sealed container, protected from light and moisture, at room temperature (15–25°C) in a well-ventilated, dry area. Keep away from strong oxidizing agents, acids, and sources of ignition. Ensure appropriate labeling and store in accordance with relevant chemical safety protocols and local regulations. |
| Shelf Life | The shelf life of 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine is typically 2–3 years when stored properly. |
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Purity 98%: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where high analytical yield and minimal impurity formation are achieved. Molecular Weight 344.39 g/mol: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine with molecular weight 344.39 g/mol is used in medicinal chemistry research, where accurate dosing and formulation reproducibility are ensured. Melting Point 156°C: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine at a melting point of 156°C is used in solid-phase synthesis, where optimal thermal stability during processing is maintained. Solubility in DMSO: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine with solubility in DMSO is used in in vitro biological assays, where homogeneous sample preparation and reliable assay performance are supported. Stability Temperature up to 120°C: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine with stability temperature up to 120°C is used in chemical process development, where compound integrity is preserved during reaction scaling. Particle Size ≤10 µm: 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine with particle size ≤10 µm is used in formulation of research reagents, where fast dissolution and uniform dispersion are accomplished. |
Competitive 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Manufacturing chemicals from the ground up takes more than a technical recipe. It takes discipline, patience, and clear standards. Over time, our team has handled a broad array of heterocyclic compounds. Some have challenged us with stability quirks or solubility issues. The synthesis and purification of 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine presents a practical case in the value of controlled environments—moisture tightness and exact pH adjustment mean the difference between meaningful yield and wasted time.
Our process leans on our own in-house route. We trust established raw materials, sourced through long-standing supply relationships, and rely on daily vigilance in monitoring reaction kinetics. On the shop floor, each batch undergoes manual inspection during critical points—color shift and precipitation remain early signs of successful conversion and complete crystallization. This is where we keep our main focus, because the moment we get lazy with sampling, we pay with yield, and down the line, the customer pays through performance dips in their application.
There’s a misconception that all specialty pyridine derivatives are just another cog in the fine-chemical wheel. They aren’t. What sets 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine apart comes down to the unique reactivity provided by the triazole ring. This structure locks in stability, while the nitrobenzyl and sulfanyl substitutions allow easier modifications. Chemists developing new fungicides and other agrochemicals see these features as doors to new patentable families, not as end points. Our product finds its way into early-stage development and pilot runs. Typically, research centers request small lots, but once their programs pick up, the demand moves to kilo scale.
Every drum and flask we fill leaves our facility with a record of its journey—GC-MS data, purity confirmation, stability records, and documented handling of even the smallest batch. Colleagues often ask how we keep quality so even. The truth is, strict adherence to in-process controls rules every step. Fine chemicals, especially those saddled with both air sensitivity and trace impurity risks, don’t forgive shortcuts. If a process parameter drifts, we halt and resolve—there’s no benefit in pushing product out that could fail in customer validation. We produce technical and research grades and often work up to 99% purity. We strive for low residual solvent levels and keep tight control over residual heavy metals, knowing that even a handful of parts per million can ruin downstream catalytic transformations.
On our shop floor, we know the equipment inside out. Glass-lined reactors, dedicated for this family of compounds, see preventive maintenance three times more frequently than industry-typical schedules. We inspect seals and stirrers precisely to prevent trace contamination—off-smell or discoloration often indicates a stubborn impurity or a missed cleaning step. This isn’t paranoia; it’s learned from running into issues during earlier years, where one overlooked gasket loaded a full campaign with silicon traces.
Consistency is never accidental. Our technical team runs not only standard HPLC and GC checks, but cross-verifies with NMR and sometimes FTIR. If we spot an anomaly, we isolate and analyze that lot further or—if needed—reject it outright. Lab books fill fast, but so does the trust customers place in us. While no chemical process runs with zero risk, we throw resources at traceability because we know a reliable supplier stays in business as long as the customers’ own processes run without unplanned troubleshooting.
Our research team keeps their tools sharp by engaging with academic journals and conference circuits. The role of this compound in triazole-based chemistry is only widening. Some years, we field calls from university groups hunting for milligram amounts to screen for antitumoral or enzyme-inhibition activities. Their needs shape how we offer this product—multiple grades, optional documentation for regulatory use, and flexible lot sizes.
Interestingly, university-industry consortia spark a lot of process tweaks. Projects run by European and North American teams push us to adapt documentation to particular requirements, sometimes involving isotope labeling or more stringent residual solvent data. We see that as a cue to invest in new analytical equipment—mass spectrometers capable of sub-ppm detection—and it pays off, not just for meeting those orders but because it raises our bar for every client.
That culture of readiness reflects in the warehouse as well. Each shipment leaves with full trace records. We keep backup retention samples and sign off on conditions of storage and transport. The type of packaging matters—HDPE drums or glass bottles, depending on stability. We ship with desiccants when required, but we avoid unnecessary overpackaging. When collaborating with partners in regions with high humidity, we’ve switched up containment solutions so quality holds up from departure to delivery.
The choice to focus on this specific compound as a product of our own synthesis track owes to several differences that show up both in handling and application. A few years back, we regularly fielded requests for similar triazolyl-pyridine products but found inconsistent market options: spotty purity, mixed isomer content, and little support for analytical needs. We already ran pyridine and triazole synthesis lines, so retooling to manage the sulfur and nitrobenzyl group, as well as the stability aspects, made strategic sense.
Compared to other 1,2,4-triazole derivatives, this product carves out a niche because the sulfanyl linkage opens up handles for more chemistry. Medicinal chemists use this site to graft on further substituents, and in material science, the resistance to oxidation means their testing matrix won’t skew from unwanted reactivity. Not every triazole can claim this profile, especially not those with more labile groups that break down in open air or need a glovebox for every transfer.
Lab-scale suppliers sometimes settle for 95% or even lower purity, particularly in rapidly moving research markets. We know that for screening, a single unknown peak might mean the difference between an artifact and a real result. Here, clean spectral lines are not a luxury—they underpin actionable scientific work. Our process sticks at or above 98% for most production runs, and we are honest about the remainder: residuals are almost always structurally related intermediates, and we document them.
The model we’ve crafted over years focuses on keeping both precision and flexibility. Whether it’s custom batch size, alternate grade specification, or customer-driven quality documentation, we offer what our experience tells us will support critical research. This sets our offering apart from generic catalogue suppliers, where little dialogue happens between process chemist and product user.
We field questions and requests every week. Many customers move quickly—sometimes needing extra documentation, sometimes flagged by an unexpected chromatographic impurity. Instead of stonewalling or hiding behind generic answers, we talk honestly about our process windows. If strict impurity specs block immediate shipment, we offer interim data and discuss options. It’s taught us that trust builds batch by batch, not by sweeping claims or boilerplate promises.
In this business, few things matter more than clarity. Researchers may face stalled projects if a material fails an internal QC check; scale-up teams can lose weeks if their building block delivers different results from pilot to production. We see our role less as a passive vendor and more as an extension of their lab bench. Clients rely on both the physical product and the willingness to talk through edge cases and real-world constraints. If a new project needs a smaller or larger lot, unconventional packaging, or enhanced stability protocols, we adapt, because non-standard needs come with the territory.
We continue bridging feedback into product modifications—not blindly, but by weighing feasibility and risk. Several years back, a series of requests for finer particle sizing prompted us to overhaul milling protocols. It meant more screening and investment in equipment, but resulted in a material that blended more easily in customer formulations. Sometimes changes come from persistent issues flagged by returning customers: for instance, we recently reduced bottle headspace to cut oxygen content in our highest stability grade, directly addressing concerns logged from a formulation specialist at a pharmaceutical research site.
Even with decades of combined experience, surprises happen. Triazole chemistry rarely sits still; small variations in temperature, from a cold winter to a humid summer, have tripped up more than one synthesis line by shifting reaction rates or influencing solubility. When production hits a snag—such as an uncharacteristic byproduct appearing in spectra—we pull the batch and break down each process variable. Recovering means re-examining not just starting material purity but equipment cleaning and even instrumental calibration. Complacency in these cases only breeds repeating mistakes.
As standards for environmental and worker safety evolve, we keep adapting—not only to keep our workforce safe but also to ensure finished product leaves no unwanted residues, as many clients now must meet stricter regulatory scrutiny. Our EHS department crosses checklists with product development—what cleaning agents we use, how we handle solvent disposal, and how we label for international transit. This attitude raises our entry barrier but pays for itself through better relationships and repeat orders.
Every product batch tells its own story. Some go straight to screening. Others seed long-term programs with repeat orders and larger scale commitments. We’ve seen more regulatory requests for extended impurity profiling, requests that five years ago would have seemed overkill. We meet these with expanded analytical methods and transparent reporting—because failing to grow with these demands soon shuts any door to serious research partners.
Investment doesn’t land only in glass and steel. It’s in time spent understanding emerging customer needs and changes in the scientific landscape. This pyridine-triazole system teaches us about the shifting boundaries between academic and industrial chemistry. Markets that once described such chemicals only as obscure intermediates now view them as core reagents, with bright spots in agriculture and emerging materials science, including organic electronics and specialty pigment research.
Our process control advances every season. We run process intensification studies and regularly rethink how our yields and material balances can improve. Real gains have come from introducing real-time process analytics—temperature and pressure monitoring hooked into digital logbooks, with staff trained to interpret and act on deviations before a batch drifts. We budget for team development as heavily as for equipment upkeep; a well-trained staff pool has so far meant smoother troubleshooting and fewer process upsets.
We also look out for supply chain disruptions—global events have taught us not to rely on single points of failure. By maintaining secondary supplies and raw material reserves, we keep up manufacturing even as larger markets experience shortages or delayed shipments. This pays off both for the business and for end users, who depend on us to deliver without unexpected lapses.
We don’t just supply a formula. Years working closely with university labs, process development teams, and pilot plants shape our direct communication style and responsiveness. We understand the need for timely shipment, reproducible results, and reliable documentation for grant audits or patent filings. For new customers, we give a clear run-down of typical lead times, batch-to-batch reproducibility stats, and any anticipated variance as new scale-up milestones approach.
Throughout the years, specialized compounds like this have shown a pattern: first, cautious interest, then broader adoption, and eventually, integration into standard workflows. In many cases, early adopters bring back stories—from success in rotary evaporation to frustration with co-precipitation in new solvents—that help us adjust both process and advice. We chart these inputs, mapping practical tips into improved technical data sheets and packing instructions.
Our outlook emphasizes that chemicals like 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine gain their market foothold not by a number on a specification sheet, but through sustained, quality-driven support and a feedback-driven supply partnership.
Any company can list a compound, but few take the time to document, iterate, discuss, and deliver on shifting customer expectations. After years handling triazole and pyridine chemistry, both in process and R&D, we confidently admit every new inquiry tests our adaptability. Finding better ways to meet user requirements, tracking evolving trends in analytical chemistry, or responding to one-off requests for special documentation—all contribute to making this more than a commodity.
We see ourselves as a technical partner, not only because we support custom orders, but because dialogue on sample handling, batch scalability, and end-use challenges comes naturally after spending years both inside and outside of the lab. We approach projects as collaborations, tuning batch parameters, documentation, and supply chain solutions in direct response to research and production demands.
The business of manufacturing 3-{4-methyl-5-[(4-nitrobenzyl)sulfanyl]-4H-1,2,4-triazol-3-yl}pyridine demands unflagging attention and open, fact-based communication. Every bottle shipped carries not just a label, but the quiet assurance of careful planning, scientific rigor, and an always-on feedback loop with the community that drives future progress.
