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All Right Reserved
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HS Code |
724538 |
| Product Name | 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride |
| Cas Number | 52530-55-1 |
| Molecular Formula | C7H24Cl4N4 |
| Molecular Weight | 298.12 g/mol |
| Synonyms | Tren Tetrahydrochloride; Bis(aminomethyl)propane-1,3-diamine 4HCl |
| Appearance | White to off-white crystalline powder |
| Solubility | Soluble in water |
| Melting Point | 240-250°C (decomposes) |
| Purity | Typically ≥98% |
| Storage Conditions | Store at room temperature in a tightly closed container, protected from moisture |
As an accredited 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500g of 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride, sealed in a white, high-density polyethylene bottle with tamper-evident cap. |
| Shipping | **Shipping Description:** 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride should be shipped tightly sealed in a moisture-resistant container, protected from light, and kept at room temperature. Handle with care as an irritant. Proper labeling and documentation according to chemical safety regulations (including hazard and precautionary statements) must accompany all shipments. |
| Storage | Store **2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride** in a tightly sealed container, protected from moisture and light. Keep in a cool, dry, and well-ventilated area, away from incompatible materials such as strong oxidizers. Label the container clearly, and follow all relevant chemical hygiene and safety protocols. Use appropriate personal protective equipment (PPE) when handling this chemical. |
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Purity 99%: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Molecular Weight 252.14 g/mol: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with molecular weight 252.14 g/mol is used in polymer modification, where it provides precise control of polymer chain structure. Melting Point 240°C: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with a melting point of 240°C is used in high-temperature epoxy formulations, where it enables improved thermal stability. Viscosity Grade Low: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride of low viscosity grade is used in resin curing processes, where it allows enhanced penetration and uniform cross-linking. Particle Size ≤ 50 μm: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with particle size ≤ 50 μm is used in coating applications, where it ensures smooth dispersion and superior surface finish. Stability Temperature up to 200°C: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with stability temperature up to 200°C is used in specialty adhesive manufacturing, where it maintains adhesive integrity during thermal processing. Hydrochloride Salt Form: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride in hydrochloride salt form is used in aqueous formulations, where it promotes enhanced solubility and processability. Solubility in Water > 100 g/L: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with solubility in water > 100 g/L is used in bioconjugation chemistry, where it facilitates rapid reagent dissolution and homogeneous reactions. Assay ≥ 98%: 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with assay ≥ 98% is used in chelating agent preparation, where it maximizes the efficiency of metal ion capture. Low Heavy Metals Content (<10 ppm): 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride with low heavy metals content (<10 ppm) is used in fine chemical synthesis, where it reduces contamination and ensures product purity. |
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2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride sounds like something out of a complicated chemistry class, but for those working in polymer science, biochemistry, or industrial synthesis, it’s a key player in advancing technology and improving processes. Known for its unique arrangement of amine groups on a branched hydrocarbon chain, this molecule stands apart from the generic amine-based agents found in traditional labs. The tetrahydrochloride salt, which many researchers choose for greater stability, dissolves easily in water and offers reproducible results in both small-scale reactions and larger industrial batches. Its white crystalline form is familiar to laboratory professionals who prefer compounds with good handling and long shelf life.
The model 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride, often referenced simply as a branched tetraamine, features four amine groups extending from a propane backbone. This structure influences reactivity and compatibility across various synthesis tasks. The compound usually appears as a high purity powder, with water content and residual solvents strictly controlled. This level of chemical purity means fewer contaminants in sensitive research and manufacturing environments, something anyone who has tried to troubleshoot side reactions will appreciate.
Lab technicians often check melting points, solubility in common solvents, and the transparency of aqueous solutions, all crucial in applications from biochemical buffer systems to complex material synthesis. By combining reactivity with reliability, the product becomes a staple on the shelves of chemical suppliers who value repeat customers and tight quality standards. I’ve come to trust that consistency in chemicals prevents a lot of headaches down the line, especially during scale-up or transfer to pilot plants.
Polymer scientists know this tetraamine as an effective crosslinking agent. Its molecular design allows for multiple connections per molecule, which makes it ideal for curing epoxy resins or producing specialty plastics with improved strength and flexibility. Unlike standard diamines, the branched format handles higher density crosslinking, so materials resist deformation in harsh environments. I’ve watched adhesives prepared with this compound outperform traditional choices, keeping laminates and fixings tight in construction or aerospace parts exposed to temperature swings.
Beyond structural materials, researchers use this tetrahydrochloride in protein binding studies, nanoparticle modifications, or as part of analytical buffers where reliable pH control matters. Solutions based on the compound don’t just buffer — they provide cationic sites that can interact with biomolecules, enhancing selectivity for certain proteins or enabling sensor development. I remember students in a protein purification workshop reaching for this compound after less robust buffers failed to separate key fractions. The frustration shifted to satisfaction quickly, all thanks to a better molecular scaffold.
Since it dissolves well, the tetrahydrochloride form replaces more cumbersome or unstable amine sources in analytical labs needing precise calibration. Environmental monitoring kits, used by field teams to detect contaminants, often draw from sample prep protocols built around this compound. Its ease of use enables accurate results, especially under tight timelines.
Plenty of amines fill catalogs, but few offer this blend of compactness, charge density, and branching. Traditional ethylenediamine or hexamethylenediamine compounds serve well enough for simple linkages, but they lack the spatial arrangement necessary for denser, three-dimensional networks. The branched design of 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride opens opportunities that linear molecules just can’t access. This means a scientist can build more intricate architectures or stabilize fragile structures in new polymers or analytical platforms.
The tetrahydrochloride salt also avoids the issues tied to less stable or more volatile free bases. I’ve seen expensive lab setups stall due to amines that evaporate or react with air, ruining experiments or spoiling months of work. With this compound, the increased shelf life and reduced odor make storage and handling straightforward. Fewer headaches with labeling, shipping, and local safety requirements keep labs focused on research instead of paperwork.
Many suppliers try to market functionally equivalent diamines and triamines, but users notice the handling differences and performance gaps. The added amine groups, packed closely together but spaced for maximum effectiveness, bring measurable improvements to crosslinking or binding. New researchers coming in from academic backgrounds are often surprised at how fast they see changes in reaction times and yields, a testament to the cumulative learning passed down from senior chemists.
Accelerating progress in materials science and biotechnology hinges on the availability of reliable, versatile building blocks. 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride allows teams to push boundaries in product innovation, high-throughput screening, and advanced fabrication. With new challenges like stronger composite materials or better diagnostic sensors, having access to this compound means fewer constraints during early-stage development.
It also matters for workforce efficiency. Too much time gets lost on quality control when base chemicals vary from batch to batch. Paying attention to source and consistency reduces errors and builds trust within a research team. I’ve seen junior colleagues become experts much faster when they work with high-purity reagents, giving them confidence and shifting their focus toward creative experimentation rather than troubleshooting impurities.
End users in pharma appreciate the safety and clarity that comes from transparent supply chains around critical chemicals. The trend toward traceability and open audits means that even a small supplier has to meet higher expectations. Because this compound is already familiar to regulatory agencies and institutional review boards, its adoption into new workflows faces fewer hurdles.
Skepticism around specialty chemicals often stems from exaggerated marketing or unsubstantiated claims, but the track record of 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride speaks for itself. Journals report transparent results from repeated studies, and independent labs regularly cite it as a key ingredient. The compound doesn’t promise miracles, just reliability across thermosetting, bioconjugation, or advanced separation tasks.
Complication comes mostly from scaling up or adapting protocols for new applications. Here, user experience matters as much as molecular design. Practitioners with hands-on time in industrial plants or contract labs can provide insight that keeps projects moving forward. Documentation, regular analysis, and open conversations across departments help ensure every batch performs as expected, especially with compounds like this where small changes in storage or handling can tip the balance.
Professionalism also comes through in how providers respond to questions, complaints, or requests for documentation. Earning trust takes more than making claims—it requires accountability. The acceptance of this compound by researchers and engineers across the globe roots itself in those principles, which foster repeat business and successful results.
Some users wrestle with the challenge of integrating new building blocks into established processes. It helps to start with detailed trials, small-batch prototypes, or side-by-side comparisons with existing amine-based agents. Collaborating with technical support teams, drawing on published research, and learning from industry forums all play a part. Particularly in fields like bioconjugation or analytical separations, subtle tweaks to concentrations, temperature, or pH influence end results, so data-driven troubleshooting is invaluable.
Waste management and environmental safety raise important concerns for any widely-used chemical. Responsible disposal practices, robust data sheets, and training for lab teams help minimize hazards. Since the tetrahydrochloride salt offers lower volatility and easier containment, risks associated with inhalation or unintentional spills drop compared to more reactive amine compounds. Moving toward greener alternatives presents a long-term challenge. Until truly biodegradable or benign substitutes become available that match the performance profile, careful stewardship remains essential.
Education can close knowledge gaps in both product selection and application. Workshops, industry partnerships, and peer-reviewed journals serve as effective vehicles for spreading reliable information about best practices. Over time, as more users share their successes—and failures—the broader community benefits. New applications often spring from these exchanges, ensuring that both efficiency and safety stay at the forefront.
Progress in science and technology relies not just on innovation at the cutting edge, but on the consistent, transparent supply of foundational materials. 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride has found its place by offering reliability where it counts—easy handling, broad compatibility, and proven results across disciplines. Its strengths aren’t limited to any one field. From construction to biotechnology, its solid reputation comes from actual field performance, not just what’s printed on a spec sheet.
Adopting any new material comes with transition costs, training time, and adjustment periods. Experienced chemical suppliers can ease these transitions by offering technical resources, on-site demonstrations, or data sharing. This builds mutual respect with end users and accelerates the learning curve for those shifting to updated protocols.
As regulations tighten and performance standards climb, only those products that can meet scrutiny hold their place in critical workflows. The robust documentation, ease of regulatory acceptance, and repeatable results of this compound keep it in demand. Lab directors responsible for both budgets and outcomes appreciate that a little investment in quality avoids bigger costs from failed projects or compliance issues.
Through years of working with both standard reagents and high-performance chemical platforms, I’ve learned that a strong backbone—both literally in molecules and figuratively in people—makes all the difference. The branched amine structure of this compound proves itself in settings where linear options don’t cut it. I’ve seen team projects hinge on that extra bit of stability or reactivity, and the right chemical can unlock stalled innovation fast.
New hires benefit from hands-on mentorship paired with open access to data sheets, published articles, and real samples. Training goes more smoothly when the compound in question behaves exactly as described, batch after batch. This predictability enables smoother planning and fewer project hiccups. Teams become more adaptable, less stressed, and ultimately, more successful.
The most rewarding projects often come from cross-disciplinary teams, combining industry veterans, academic researchers, and technical staff. I’ve watched engineers building greener adhesives, biochemists tackling complex separations, and analytical chemists using this tetraamine as a cornerstone for groundbreaking sensors. Each field brings unique requirements, but the shared foundation is a chemical that does its job without fuss or surprises.
As new industries emerge and standards evolve, the demand for compounds like 2,2-Bis(Aminomethyl)Propane-1,3-Diamine Tetrahydrochloride shows no sign of slowing. Nanotechnology, biomedical devices, and environmental sensors call for components that function at tiny scales and under tight constraints. This product adapts well to those pressures, supporting both rapid prototyping and longer-term manufacturing goals.
Even as greener synthesis and biodegradability rise as priorities, users continue to rely on performance and traceability. Suppliers working to minimize environmental impact while maintaining purity and documentation will set the pace. Transparent communication, investment in R&D, and honest sharing of test results keep everyone on track toward safer chemicals and improved products.
For students, early-career professionals, and seasoned chemists alike, there’s value in choosing well-established building blocks when designing protocols or developing new products. The balance of reliability, versatility, and safety offered by this compound—along with a track record of success—makes it a solid choice in a crowded field. As research demands evolve, that legacy will keep this tetraamine front and center across industries.
