|
HS Code |
895667 |
| Iupac Name | 2-[2-(methylamino)ethyl]pyridine |
| Molecular Formula | C8H12N2 |
| Molecular Weight | 136.19 g/mol |
| Cas Number | 3056-50-4 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 238-240 °C |
| Melting Point | -47 °C |
| Density | 1.03 g/cm³ |
| Solubility In Water | Moderate |
| Smiles | CNCCc1ccccn1 |
As an accredited Pyridine, 2-(2-(methylamino)ethyl)- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical Pyridine, 2-(2-(methylamino)ethyl)- is packaged in a 100 mL amber glass bottle with tamper-evident cap. |
| Container Loading (20′ FCL) | 20′ FCL: Load 160 drums (200 kg each) totaling 32 metric tons, securely packed for Pyridine, 2-(2-(methylamino)ethyl)- shipment. |
| Shipping | **Shipping Description:** Pyridine, 2-(2-(methylamino)ethyl)- should be shipped in tightly sealed containers, packed in accordance with regulations for hazardous organic bases. Transport at ambient temperature, away from incompatible substances and sources of ignition. Ensure compliance with relevant UN, DOT, and IATA guidelines, including appropriate labeling and documentation for toxic and flammable substances. |
| Storage | **Pyridine, 2-(2-(methylamino)ethyl)-** should be stored in a tightly sealed container in a cool, dry, well-ventilated area away from heat, ignition sources, and incompatible substances such as oxidizers and acids. Keep the storage area clearly labeled and secure to prevent unauthorized access, and protect from moisture. Store under inert atmosphere if recommended and follow all relevant safety guidelines. |
| Shelf Life | Pyridine, 2-(2-(methylamino)ethyl)- typically has a shelf life of 2 years when stored tightly sealed, cool, and protected from light. |
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Purity 99%: Pyridine, 2-(2-(methylamino)ethyl)- with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Molecular weight 136.20 g/mol: Pyridine, 2-(2-(methylamino)ethyl)- at molecular weight 136.20 g/mol is used in fine chemical manufacturing, where accurate stoichiometry and compound reproducibility are achieved. Melting point 36°C: Pyridine, 2-(2-(methylamino)ethyl)- with a melting point of 36°C is used in controlled crystallization processes, where it allows for efficient temperature management and phase purity. Aqueous solubility: Pyridine, 2-(2-(methylamino)ethyl)- featuring high aqueous solubility is used in solution-phase peptide synthesis, where it enhances reaction rates and solute compatibility. Stability temperature 50°C: Pyridine, 2-(2-(methylamino)ethyl)- stable up to 50°C is used in extended-duration laboratory assays, where it minimizes degradation and ensures experimental accuracy. Viscosity 1.05 cP: Pyridine, 2-(2-(methylamino)ethyl)- with viscosity 1.05 cP is used in microfluidic analytical devices, where it provides consistent flow behavior and accurate sample transport. Low residual solvent content: Pyridine, 2-(2-(methylamino)ethyl)- with low residual solvent content is used in synthesis of active pharmaceutical ingredients, where it improves product safety profiles and regulatory compliance. Analytical grade: Pyridine, 2-(2-(methylamino)ethyl)- of analytical grade is used in chromatographic reference standards, where it guarantees detection reliability and quantification precision. |
Competitive Pyridine, 2-(2-(methylamino)ethyl)- prices that fit your budget—flexible terms and customized quotes for every order.
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We’ve spent decades developing and refining the synthesis of Pyridine, 2-(2-(methylamino)ethyl)-, sometimes referred to in the lab as N-Methylpiperazine-pyridine. Each batch runs through reactors under the watchful eyes of our production engineers, monitoring every parameter to keep everything consistent. Chemistry doesn’t take shortcuts, and we respect that. Our approach comes from real experience on the manufacturing floor, not just sales literature or secondary handling. There’s a lot more to this molecule than what meets the eye in a technical summary, and we believe in explaining precisely why that matters to formulators, researchers, and industrial colleagues.
Every lot begins with high-purity starting materials vetted for trace metals, residual solvents, and potential byproducts. We put a lot of effort into column purification and fraction control, keeping amine impurities in check. Inconsistent crystallization, yellowing, or excess moisture don’t pass our checks. The facility runs dedicated lines for pyridine derivatives to avoid cross-contamination that shows up as off-odor or side-chain analogs in final analysis. Reliable boiling point, stable color, and the right refractive index all come from this tight in-house control, not theoretical yields or outsourced repacking.
For Pyridine, 2-(2-(methylamino)ethyl)-, the most requested profile runs between 97% to 99% purity, certified by in-house GC-MS, with water below 0.2% by Karl Fischer titration. Our main bulk model supports a liquid phase at ambient temperature, which gives synthetic chemists the flexibility for direct injection or blending into solvent mixes without extensive predrying. Consistency here cuts down on wasted time repeating tests for identity or re-running columns due to unknown tailings.
We’ve seen where this molecule travels inside different labs and plants. It plays a core part in complex ligand development for pharmaceutical intermediates. The two-carbon chain linking the pyridine and methylamino groups unlocks selectivity in chiral catalyst production. It’s often chosen by med chem teams refining cancer drug scaffolds or tackling CNS targets because it offers a balance of nucleophilicity and steric access at the amine, which many simple pyridine derivatives lack. With proper handling, it lends itself to alkylation reactions and in situ protection, saving steps in custom synthesis projects.
Environmental labs have shifted to Pyridine, 2-(2-(methylamino)ethyl)- as a test reagent for organometallic sample prep, especially when other reagents introduce background alkyl chains. Polymer developers value it for fine-tuning chain transfer agent behavior; it adjusts backbone polarity without disrupting the main chain integrity. Not every pyridine substitute delivers the same performance—by-profiles, end-point color, and interaction with radical initiators can vary. Our hands-on experience lets us advise which reactor setups and downstream separation methods suit its character.
Colleagues sometimes ask, why invest in this molecule instead of picking a cheaper or more common pyridine analog? Cost matters, especially at scale, but chemical performance shouldn’t become a trade-off. Take 2-picoline or standard methylpyridine—these lack the specific amine tail needed for targeted ring modifications and complex substituent installation. Buying bulk N-methylpiperazine as a substitute doesn’t bring the pyridine scaffold’s aromatic reactivity or the same hydrogen-bond acceptor strength. Researchers have noted fewer purification headaches with a clean batch from us versus older stock bought through less direct routes. This comes down to batch aging, inconsistent packaging, and lack of lot traceability on the secondary market.
Direct manufacturer sourcing means tight integration between chemists and production teams—feedback from a customer’s failed reaction flows right back to us, leading to changes in how we monitor and stabilize raw material feedstock. This kind of agility is hard to find when relying on reps or brokers, who rarely understand how lot-to-lot variance impacts real synthetic outcomes.
Trust grows through transparency. Sourcing from manufacturers who run full lot documentation, archive sample retentions, and permit third-party audits reduces the contamination risks that have hit chemical markets. In our facility, maintenance on every reaction vessel follows detailed cleaning protocols, eliminating cross-batch ghosting that can damage downstream results. Solvent recovery units run regular cleaning validation, and our traceability extends to every barrel. Shipments include spreadsheets of analytical runs, not just certificates issued months ago or shuffled through traders.
This supply integrity means less production downtime and fewer rejected runs in client operations. For those scaling up from kilo-lab to pilot batches, we coordinate directly with their teams, sharing historical performance data—even old in-process records, if it supports client risk assessment. This open record-keeping is why multinational R&D groups continue working with us instead of chasing the shortest lead times or lowest unit costs.
Pyridine, 2-(2-(methylamino)ethyl)- can be finicky. It absorbs moisture from the air and picks up traces of CO2, slowly yellowing or gumming up equipment seals if mishandled. Drum materials matter: stainless steel gives the best protection, but it’s heavier and costlier, so we offer lined HDPE drums for large runs, maintaining chemical simplicity. Internal QC inspects every drum for micro-leaks and checks headspace gases for amine loss. On request, we freeze or layer under inert nitrogen for sensitive projects. The main goal: batches arrive as fresh as the day they left the line, not half-degraded by poor transit or sitting in an old warehouse.
Our tech folks go beyond paperwork, coaching end-users about equipment flushing, valve compatibility, and the quirks of storage temperatures. We’ve fielded calls from field chemists struggling with unit ops gum-up and diagnosed probable root causes as line residue from less pure source material—or discovered aging gaskets reacting with trace amines. Being present, instead of distant, is how mistakes get resolved instead of repeated.
Chemical buyers sometimes tell us, “Just send the results that pass”—that doesn’t cut it. Our policy is to share complete COA data, including secondary peaks, not just pass/fail summaries. End-to-end transparency about GC-MS, NMR, water content, and non-volatiles empowers researchers to judge suitability for their projects. We routinely provide reference spectra on request, helping clients validate method development or track batch-to-batch differences. This standard gives greater reproducibility—for both science and manufacturing scale-up.
Analytical openness isn’t only an internal process; we welcome third-party validation, letting independent labs verify our claims. Authenticity comes through cross-checking, not hiding behind incomplete paperwork or repackaged product runs.
There’s a difference between making a molecule from scratch and buying an off-the-shelf drum. Our team solves problems when variables break standard routine—raw material shifts, temperature swings, or minor equipment hiccups. This shows in how we react to market changes, not just in times of smooth supply. During global solvent shortages, we changed our distillation methods, secured multiple raw source streams, and kept close communication with regular clients. The whole process builds institutional knowledge, leading to better problem-solving next cycle. People see our stability and know our batches will not be a gamble.
Our teams keep detailed logs, noting every recipe revision and unexpected outcome. This approach isn’t universal in contract or toll manufacturing. Some facilities run multiple products through common pipes, introducing unknowns in the final bottle or drum. Shortcuts don’t last for complicated molecules with sensitive downstream uses.
Working with Pyridine, 2-(2-(methylamino)ethyl)- means building systems that go beyond minimum compliance. Our operations stress engineering controls and real environmental monitoring. Employees routinely check air quality and personal exposure. We invest in robust venting and backup containment, not just meeting legal requirements but minimizing community and workspace risks. When spills have happened, root cause gets published to operations and management, then reflected in improved process steps. That’s the cycle—mistake, identify, fix, share, improve.
Our refusal to cut corners on hazard controls isn’t just about regulations. Reliable chemical performance depends on safe, stable production. Too many manufacturers only react to safety guidance after it’s already a problem. Years of close calls have taught us that the cost of proactive control is far less than recovering from a serious incident.
Every chemistry-focused company needs partners invested in pushing boundaries. Whether it’s a startup running structure-activity relationship screens, or an established pharma scaling a new API intermediate, we provide the critical backbone—stable, documented, and reliable material. Our willingness to experiment on client routines has helped develop new salt forms and optimize protection/deprotection schemes for lab-scale through multi-ton runs. Our feedback cycle with formulation and manufacturing chemists often leads to subtle adjustments: moisture controls tightened for one site, or drum liners swapped to support a new transport route.
We coordinate long-term supply forecasts with R&D teams, ramping production up or down in sync with project needs instead of forcing customers to hold risk inventory. This tight alignment reduces waste, drives costs down, and lets our clients focus on their science instead of firefighting raw material shortages.
Responsible manufacturing extends beyond the plant gate. We track all our effluent—from reaction wash water to process vent emissions—and reintegrate as much as possible using on-site recovery. Regular audits from both local and international partners keep practices sharp. Waste minimization isn’t a buzzword for us; it’s measurable by reduced output and clear records of solvent regeneration cycles.
We stay ahead of regulatory changes, documenting our compliance for our entire supply chain. Our facilities have responded rapidly to evolving requirements, restructuring record-keeping systems and raw material sourcing protocols to align with standards on chemical handling, labeling, and transport. All our employees go through regular training on these topics to keep safety and transparency central.
We’ve learned that successful projects hinge on relationship-driven support, not just selling a commodity. Our technical team keeps close contact with regular users, checking in after scale-up batches ship or troubleshooting synthesis bottlenecks. Clients turn to us with questions—sometimes as unexpected as glassware compatibility or downstream purification—and we bring collective know-how to the table. This approach builds mutual trust. Word-of-mouth from satisfied collaborators fosters more business than any ad or promotion.
Collaborating on real-world R&D projects, we’ve often provided more than product: early access to upcoming process improvements, tailored packaging, or chemical blends that simplify downstream steps. This feedback loop propels new discoveries in both manufacturing and lab-scale chemistry.
Advances in drug discovery, fine chemical synthesis, and material sciences depend on partner manufacturers who do more than deliver a drum with a label. As demand for Pyridine, 2-(2-(methylamino)ethyl)- grows from both classic synthesis and novel applications, we commit to keeping the bar high—honest analytical data, open channels for support, and continuous improvement born from hands-on expertise.
Colleagues choosing a trusted partner over a marketer or distant supplier see greater reproducibility, lower risk, and better long-term value—results stemming from a culture committed to responsible chemical manufacturing at every step. We see each batch as another chance to demonstrate what decades of accumulated experience looks like in practice, not theory.
