|
HS Code |
239395 |
| Product Name | Pyridine,3-hydrazino-, dihydrochloride |
| Cas Number | 20367-21-5 |
| Molecular Formula | C5H8Cl2N4 |
| Molecular Weight | 195.05 |
| Appearance | White to off-white solid |
| Melting Point | 250-253°C (dec.) |
| Solubility | Soluble in water |
| Storage Temperature | 2-8°C |
| Synonyms | 3-Hydrazinopyridine dihydrochloride |
| Purity | Typically ≥98% |
| Iupac Name | 3-hydrazinopyridine dihydrochloride |
| Structure | C5H7N3·2HCl |
| Smiles | NNc1cccnc1.Cl.Cl |
| Inchi | InChI=1S/C5H7N3.2ClH/c6-8-5-2-1-3-7-4-5;;/h1-4H,6H2,(H,7,8);2*1H |
As an accredited Pyridine,3-hydrazino-, dihydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 g of Pyridine, 3-hydrazino-, dihydrochloride is packed in a tightly sealed amber glass bottle with clear hazard labeling. |
| Container Loading (20′ FCL) | 20′ FCL: 250 kg drums loaded securely, totaling 8 MT net weight, suitable for bulk shipment of Pyridine,3-hydrazino-, dihydrochloride. |
| Shipping | Pyridine,3-hydrazino-, dihydrochloride should be shipped in tightly sealed containers, protected from moisture and light. It must be clearly labeled and packaged according to hazardous chemical regulations. Shipping should comply with local, national, and international transport guidelines, including provisions for corrosive materials. Ensure the shipment includes safety data sheets (SDS). |
| Storage | Store Pyridine,3-hydrazino-, dihydrochloride in a tightly sealed container in a cool, dry, and well-ventilated area, away from direct sunlight, moisture, and incompatible substances such as strong oxidizers. Keep the container clearly labeled and protected from physical damage. Avoid extreme temperatures and ensure access is limited to trained personnel. Store in accordance with local, state, and federal regulations. |
| Shelf Life | Shelf life of Pyridine,3-hydrazino-, dihydrochloride: Store tightly sealed, protected from moisture, at 2-8°C. Stable for at least 2 years. |
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Purity 98%: Pyridine,3-hydrazino-, dihydrochloride with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product reliability. Melting Point 188°C: Pyridine,3-hydrazino-, dihydrochloride with a melting point of 188°C is used in organic reaction catalysis, where it provides thermal stability during high-temperature processes. Molecular Weight 188.06 g/mol: Pyridine,3-hydrazino-, dihydrochloride with a molecular weight of 188.06 g/mol is used in analytical chemistry applications, where precise quantification and reproducible results are required. Water Solubility 50 g/L: Pyridine,3-hydrazino-, dihydrochloride with a water solubility of 50 g/L is used in aqueous formulation development, where it allows for rapid dissolution and homogeneous mixing. Stability Temperature 25°C: Pyridine,3-hydrazino-, dihydrochloride with a stability temperature of 25°C is used in laboratory storage protocols, where prolonged shelf life and compound integrity are maintained. |
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Years of hands-on practice show that Pyridine,3-hydrazino-, dihydrochloride (CAS 14445-53-7) has grown into a trusted building block for both academic and industrial research labs. Production teams see it most often as a white or off-white crystalline solid, directly reflecting a focus on purity at every stage of handling. With our synthesis experience, we keep water content tightly controlled, and batch-to-batch consistency features at the heart of our quality strategy. The molecular structure supports robust reactivity, making it attractive to synthetic chemists who tackle challenging intermediates.
Out on the plant floor, the safety and reliability of this compound mean everything to those watching every drum and every sealed bag. We run standard analysis for chloride ion content and check melting points closely to weed out any runaways from spec. Through elemental analysis, we confirm every batch aligns with requirements, with hydrazine functionality ready for action. This is not just chemistry on paper — every achieved spec signals a process that has earned trust over hundreds of kilograms delivered and years of laboratory close calls, tweaks, and breakthroughs.
Pyridine,3-hydrazino-, dihydrochloride draws steady demand in fields like pharmaceutical process development, heterocycle synthesis, and specialty materials. Medicinal chemists tell us time and time again that its reactivity profile makes it irreplaceable in transformations where nitrogen-rich moieties are needed. Researchers reach for it to build libraries of novel pyridyl-based compounds, and some design routes use it as a precursor for cutting-edge anti-infective or oncology candidates.
On the materials engineering side, the pyridine scaffold and hydrazine lone pairs open up custom ligand and chelation strategies for metal complexes. This gives rise to insights for everything from catalysis to sensing technology. We constantly evaluate incoming feedback from lab partners and scale up teams. Their projects reveal that the dihydrochloride form handles moisture much better than the free base, letting them avoid inconsistent yields or unstable intermediates. Bulk chemists have proven over the years that the salt form simplifies weighing and dissolves more predictably in polar solvents for controlled reactions.
People ask how the product stands up to everyday handling — the key is its robust granulometry. Unlike more hygroscopic analogs, Pyridine,3-hydrazino-, dihydrochloride shows little tendency to cake or clump in storage, making it friendlier to weigh out by both seasoned operators and those new to bench chemistry. With our own warehouse staff’s years of feedback, containers stay sealed and material flow stays smooth even as seasons shift. Synthesis shops aiming for larger scale benefit from these physical traits, often seeing improved efficiency as a result.
The drive to supply Pyridine,3-hydrazino-, dihydrochloride came from real conversations with chemists and plant managers. For us, every batch release is the outcome of audits, trials, and focused improvements. The procedures behind each order started long before the first drum shipped — they grew from dozens of small-scale runs, tracked failures, and knowledge of common pitfalls in hydrazine handling. We stripped away legacy impurities, swapped out poor quenching steps, and locked in reliable crystallization routines.
Daily practice teaches us that factory realities never match the black-and-white of the literature. Batch-to-batch variation once threatened the stability of multi-step syntheses for our clients, so we doubled efforts on in-process checks. Now, FTIR and HPLC analyses catch the earliest hints of degradation or contamination. This shields the end-user from surprises and delivers a level of trust built over repeat orders and transparent test reports. Any unusual smell or discoloration alerts the QA crew, and shifts do not sign off until results clear spec.
Staff in our drying rooms and blending halls speak frankly: Moisture sensitivity can spell disaster for hydrazine compounds. Our technical know-how means we never neglect the basics — low humidity, inert atmo loading, and rapid packaging. By following the right methods, we prevent issues that, in the past, cost downstream biologists or pharmacologists weeks of troubleshooting. One incorrect seal or leaky liner would have meant headaches all the way down the chain, so we set standards based directly on our experience with these challenges.
Trust begins at the source. Having boots on the ground at every step means that customer feedback makes its way straight to R&D. One client spotted instability in their formulation, which sparked a round of stability trials at our pilot plant — the outcome shaped our process. Those closest to the bench know what matters most, and our teams thrive on these problem-solving cycles.
Among various hydrazine derivatives, Pyridine,3-hydrazino-, dihydrochloride stands out because of its versatility and well-documented reaction pathways. Colleagues experimenting with related compounds — from simple hydrazine hydrates to fancier aromatic hydrazines — often run into storage headaches, byproduct puzzles, or reactivity issues. The pyridine ring coupled with the hydrazino group in our compound sidesteps many of these headaches. Analytical teams show that this structure steers transformations with fewer side products and simpler work-ups, especially compared to less stable alkyl-substituted hydrazines.
Talking directly to synthetic chemists, they value more than just a finished compound. Small differences in melting range or chloride acidity cause lasting impacts on conversion rates down the line. Our labs prioritized these details during development, because early partners taught us where process slippage leads to trouble. It can make or break a kilo-scale synthesis whether the product dissolves evenly, with predictable pH changes, or presents no off-odors after months in storage. So, while many generic sources skip key quality controls, our batch histories keep every lot documented and retraceable.
We have learned over time that not every supplier cares about shelf life or controlled packaging. Pyridine,3-hydrazino-, dihydrochloride comes with resilience, resisting the kind of clumping and color change found in less-than-ideal equivalents. Our partners in pharmaceutical R&D, annoyed by yellowing or oiling out in competitive materials, turned to our output for predictable endpoints. This means time saved on rework and less effort wasted on troubleshooting.
Various routes to hydrazine functionalized pyridines exist. Yet, only through tight process discipline and feedback loops have we been able to guarantee chloride content, known melting properties, and resistance to degradation. This advantage stretches from five-gram analytical samples to drum quantities, and each time we adjust controls with actual data from real users.
Medicinal and organic chemistry remain the home ground for Pyridine,3-hydrazino-, dihydrochloride, especially as researchers search for new biologically active cores. We’ve watched the compound move from library screens to full-scale pilot runs for advanced intermediates. Cheminformatics feedback from biotech labs indicates that this molecule lends itself well to SAR development, due to both its flexibility and compatibility with oxidative or condensation conditions. Staying involved with downstream teams, we see how purity translates to cleaner analytics, lower false positives, and greater confidence at scale.
Specialty chemicals and dye research also depend on robust sources for building blocks. Teams ask for product that does not bring unexpected side products or polymeric byproducts. We monitor these aspects closely to sidestep yield losses or structural uncertainty. Synthesis engineers want the comfort of working with something whose background and storage behavior is a known quantity. In one stretch of high-humidity production, our dry room protocols prevented the dreaded clumping seen in lower-quality hydrazine compounds.
Whereas alternative materials introduce doubts — unwanted odors, unreliable pH, inconsistent foil pouching — Pyridine,3-hydrazino-, dihydrochloride keeps its form and function for extended periods under controlled storage. Openness on shelf-life data and willingness to rerun tests for any flagged batches is standard practice. We refuse to simply pass along the product; we own responsibility from the first recrystallization to the final shipment.
Generation after generation of chemists continue to innovate, and our job stays the same: provide compounds that add value through reliability, not just availability. Teams in the field deserve to know they are not fighting their raw materials at every turn. Our production specialists keep gathering hard-earned lessons and sharing them among new hires — from environmental monitoring to test methods — so today’s experience prevents tomorrow’s missteps.
We invest in new instrument validation, bench trials, and regular skill retraining. Lab managers see how this approach stops errors cold before they ever land on a customer’s bench. Strong process documentation and repeatable checks are not simply regulatory paperwork, but life lessons in keeping chemistry clean and reproducible. Over decades, keeping tight records of each process helps root out minute sources of instability, smoothing out supply chains even amid unplanned events.
Clients ranging from academic explorers to international pharma players teach us something new with each project. Their honest feedback on formulation, mixability, and analytical outcomes closes the loop for continuous improvement. We do not rest on decades-old processes — instead, we update procedures with every meaningful suggestion, watching the data guide changes. This culture of mutual support and feedback means each batch strives to resolve yesterday’s pain points.
Anyone relying on unique heterocycle intermediates knows the headaches bad batches can cause. Inconsistent moisture, off-color solids, or variable reactivity cost time and may derail entire drug development programs. By keeping lines of communication open, our teams learn to spot root causes and adapt practices before issues leave the site. Problems flagged during scale-up — whether appearance, stability, or solubility — lead directly to technical troubleshooting and honest reporting to our customers.
Solving those problems means stepping into the lab, running test syntheses, and staying accountable until things work as they should. Improvements in process validation and tighter environmental controls came from shop floor wisdom and feedback from scientists trying new reactions. Not every attempt works out — but every cycle generates insights and prevents repeated mistakes. Building an environment where questions and doubts are addressed openly pushes our operation forward.
Looking ahead, pressure remains to support new areas: green chemistry, reduced-waste syntheses, and custom derivatives. Input from external R&D groups prompts us to investigate alternative crystallization and refining processes. By following changes in regulatory attitudes towards hydrazines and maintaining close control of environmental impact, we align manufacturing with both safety and innovation.
Passing down respect for every kilogram, every lot, and every test result is core to our operation. Those of us in daily contact with Pyridine,3-hydrazino-, dihydrochloride keep raising the bar through curiosity and hard-earned experience. Our work is measured not just by certificates but by the smooth progress of our customer’s projects. Chemists, operations leads, and lab technicians who try different sources grow loyal to suppliers who treat their needs as more than a transaction. We recognize that behind every order is another team counting on things working right the first time.
Trust does not come from fancy brochures or stock photos but from real performance under pressure: in production, in shipping, and on the bench. We tackle failures head-on and record every lesson, building an ever-more resilient supply and support system. If a process can be made cleaner, faster, or more energy-efficient — we take that road. And we invite feedback from lab partners at every rung of the chemistry ladder. Pyridine,3-hydrazino-, dihydrochloride continues to push boundaries for those willing to engage, retry, and refine. Every success today owes a debt to the collective knowledge and hands-on learning of those who came before us.
Daily commitment shapes every phase from start to finish — raw material inspection, purification, drying, and safe packaging. Each new order reflects our continuous pursuit of cleaner, more reliable chemistry. By standing firm on quality and staying open to real-world experience, we aim to keep providing the solid foundation that modern research and manufacturing deserve. We keep eyes open, hands steady, and always remain open to ways to serve the next challenge in the field of advanced organic synthesis.
