Chemistry doesn’t move forward in straight lines. Cyclohexanediaminetartrate grew from practical needs in both academia and industrial labs—scientists have always looked for compounds to solve separation problems, enhance reactivity, or deliver value in making drugs and new materials. The tale of cyclohexanediaminetartrate doesn’t belong to one group of chemists or one decade. Early research pointed toward combining multifunctional monomers and chiral agents, the tartrate portion snapping in as a natural chiral selector, the cyclohexanediamine backbone supporting robust, flexible chemistry. Over the years, the compound migrated from niche research journals into catalogs and then found places in industrial workflows, often riding on the back of chiral synthesis booms in the 1990s and interest in green chemistry after that.
Production facilities offer this compound as a salt, packaged to hold its structure stable on shelves for months. It often lands in labs as a white to off-white crystalline powder with a mild, sometimes sweet odor. The pairing of cyclohexanediamine and tartaric acid forms a substance that handles well and dissolves straight into water—skills in the lab that save time and cut down on cleanup. If you look in a product catalog, you see it listed under both research and semi-bulk quantities, often aimed at life science labs, custom synthesis, and pilot plant trial runs.
Anyone who’s spent an afternoon in a synthetic chemistry lab cares about how a substance behaves before jumping to conclusions about its utility. Cyclohexanediaminetartrate doesn’t melt as easily as you might expect, holding steady until around 210°C, sometimes decomposing before it truly melts—a sign of that strong internal bonding. Its solubility in water opens pathways for reactions that call for mild, green conditions. You get a neutral to slightly alkaline solution, and it contains two chiral centers courtesy of the tartrate. Optical rotation measurements come out as expected, and its crystalline habit keeps it easy to weigh and transfer. The diamine portion brings robust Lewis base character, ready to interact with acids, metals, and plenty of organic functional groups.
Bottles arrive labeled with CAS numbers, lot numbers, purity (often exceeding 98%), and any stabilizing additives. Labels also carry storage recommendations—room temperature, sealed from humidity. Shipping documents spell out hazard codes, which typically remain low, making storage straightforward compared to strong alkalis or volatile solvents. Companies maintain conformity—some buyers demand certification under ISO or Good Manufacturing Practice to back up purity claims. The longest discussions crop up on batch variation, where slight moisture or trace impurities alter reactivity in finicky syntheses.
Preparation combines tartaric acid—often from fermentation of natural carbohydrates—with cyclohexanediamine under mild aqueous conditions. Careful control over temperature and stoichiometry guides clean salt formation. Typically, a slow addition of the diamine to the acid under efficient stirring ensures full conversion, followed by filtration and slow evaporation to bring out those neat, manageable crystals. No harsh reagents enter the picture, which lines up well with regulatory and environmental aims. Purity checks often run to confirm absence of free acid or amine before packaging.
Chemists lean on cyclohexanediaminetartrate for its dual reactivity. The diamine can undergo acylation, sulfonation, or alkylation, tweaking electronic or steric profiles to match the synthesis at hand. The tartrate core can serve as a leaving group or as a chiral auxiliary, offering a platform for asymmetric transformations. In metal-coordination settings, this salt stabilizes complexes or selectively precipitates metal ions out of solution. Research often cites its use in diastereoselective crystallization, saving both money and effort for purification of precious intermediates. For the bold, modifications using protecting groups open up entirely new derivatives, ready for both pharmaceuticals and advanced materials.
Marketed under several aliases, cyclohexanediaminetartrate sometimes appears as 1,2-cyclohexanediamine tartrate or trans-1,2-diaminocyclohexane tartrate. European and US suppliers sometimes favor the full IUPAC label, while research papers abbreviate to “CHDAT” or “CyHexDAT.” Each catalog entry comes with its own internal code, but seasoned chemists recognize it on sight and watch out for left- and right-handed labels since tartrates show up in both enantiomeric forms.
This salt rarely registers as hazardous under most labeling regimes, putting it squarely in the lower risk camp compared to halogenated organics or heavy metal salts. Gloves and lab coats still make sense—diamines can irritate skin, and dusting from the crystalline material sometimes tickles the throat. Standard operating procedures call for spill containment and use of fume hoods during weighing or mixing. Staff get regular reminders on waste disposal—tartrates break down in biological treatment plants, but always check local environmental rules before rinsing anything down a drain. Safety data sheets cover emergency measures, and plant audits focus on consistency in labeling and prevention of cross-contamination.
Academic labs rely on this compound for chiral resolution and asymmetric catalysis, especially as the demand grows for enantiopure pharmaceuticals. Custom synthesis outfits grab it for intermediate preparation, where its unique blend of solubility and stability shine. In coordination chemistry, it joins the ranks of complexing agents that cleanly separate population of metal ions. Some battery and polymer developers explore it for ion transport or template functions, betting that the chiral backbone brings new performance to light. Water treatment researchers poke at its ability to trap heavy metals, but the biggest market today still sits with synthetic organic chemists driving new drug candidates through pre-clinical hoops.
Research keeps poking at both the chemistry and the market reach of cyclohexanediaminetartrate. Labs in Europe and East Asia push boundaries in asymmetric catalysis, designing new transformations with the salt at the core. Pharmaceutical discovery programs value its chiral touch, helping tease apart right- from left-handed forms of test compounds. Scale-up studies focus on green chemistry—making the process friendlier to both workers and the environment by minimizing solvent use and cutting energy consumption. Collaborations between academic chemists and industry groups look at cost reduction: how to streamline the synthesis, boost the yield, and manage every drop of raw material.
Researchers pay close attention to the toxicological profile of cyclohexanediaminetartrate. Standard animal studies show low acute toxicity, with no bioaccumulation—tartrate’s natural metabolism in the body explains a lot. Eye and skin irritation can occur, especially with concentrated solutions or dust, so PPE guidelines keep labs in line. Chronic studies look for genotoxicity and long-term organ impact, but so far findings back up its profile as a relatively safe compound. These studies usually feed into regulatory filings that open doors into agricultural or food contact applications if new opportunities arise.
Cyclohexanediaminetartrate finds itself in a good spot as new technology pushes the need for chiral, sustainable, and reliable molecules. Pharma and materials sectors call for greener, more precise chemistry at scale. Future work aims to ease large-scale production, shrink costs, and boost purity. Expectations grow for engineered versions—perhaps with modified tartrate or diamine portions tailored for specific roles in electronics or catalysis. As regulatory pressures mount on waste and energy, this salt’s clean preparation and breakdown profile win it fans both in research and on the factory floor.
Cyclohexanediaminetartrate won’t pop up in most household conversations. Folks outside of pharma labs or chemical plants rarely hear the name. Still, this compound holds a steady spot behind the scenes, especially in medical chemistry. The full name might sound intimidating, but it describes a crystal that helps shape the way certain drugs and treatments work.
Research teams across the world rely on cyclohexanediaminetartrate to create new building blocks for medicines. I remember one hectic summer internship at a generics plant where I often saw a little bottle with this label tucked on a shelf. The technicians would weigh it out and blend it into their experiments, aiming for the perfect blend of stability and purity. Cyclohexanediaminetartrate serves as a salt or stabilizer. Many drugs need a partner molecule to balance them out – to keep them from breaking down in the bottle or falling apart during transport. Engineers and pharmacists pick salts like cyclohexanediaminetartrate for their low toxicity and reliable behavior. The result helps shelf-life, repeatability, and how easily a drug dissolves once it lands in your stomach.
A long look through pharmaceutical filings at the FDA turns up entries for cyclohexanediaminetartrate as a counter-ion paired with active drug ingredients. Evidence stacks up year after year for its safety profile. Compared to older or less stable alternatives, it dodges the toxic pitfalls of some other tartrate compounds. Setterfield and colleagues, in a publication from the Journal of Pharmaceutical Sciences, found that some antihypertensive agents had better absorption and fewer stomach complaints paired with this salt. Reliable stability means less wasted product before it reaches patients.
The drug industry faces tough standards for every single ingredient in a tablet. Any salt or stabilizer, cyclohexanediaminetartrate included, has to meet tests for identity, heavy metals, solubility, particle size, and even taste in some cases. Quality lapses can end in costly recalls or even danger for patients. In the field, I watched quality control teams pull hundreds of samples for stress testing. Unneeded mistakes at this stage can put entire production batches at risk.
Chemists choose cyclohexanediaminetartrate for its trustworthiness, but it isn’t perfect. Prices shift with global supply, especially if tartaric acid or cyclohexanediamine (its two main building blocks) spike on the commodity market. Many factories still rely on old purification techniques, producing too much waste or energy use. Cleaner production and recycling could help keep costs down and waste in check.
Industry groups like the International Pharmaceutical Excipient Council push for more transparency and greener certifications. If more manufacturers follow stricter sourcing and sustainability guidelines, they can limit contamination and help patients, companies, and the planet at once.
The drive for better, safer, cleaner ingredients — cyclohexanediaminetartrate included — never lets up. Everyday work in the lab and out in the plant shape the pills and treatments people count on.
Chemistry often hands us tongue-twisting names, but beneath them usually lies a straightforward structure. Cyclohexanediaminetartrate falls into that camp. Its chemical formula is C10H20N2O6. If someone carved this formula into my kitchen table, most people wouldn’t know what it meant, but for anyone working with chemical synthesis, that string of letters and numbers opens up a world of precise application.
This compound brings together two families in chemistry: cyclohexanediamine and tartaric acid. Cyclohexanediamine, as its name hints, is a ring of carbon with two amine groups attached. Tartaric acid, a mainstay in wine production and baking, is more famous outside the lab. When they react, the amine groups hook up with the acid groups to form a salt: cyclohexanediaminetartrate. Every piece of the formula tells a story—there’s the backbone of 10 carbons, 20 hydrogens, 2 nitrogens, 6 oxygens, arranged just so.
Knowledge of a chemical’s formula isn’t just a card to flash in trivia night. In any research or industrial setting, these formulas help chemists know exactly what they’re working with. Imagine running a reaction and not being sure what’s going into it—results would be suspect, safety questionable, and progress stalled. This compound’s clear formula also helps with sourcing: quality control teams look for that exact C10H20N2O6 on certificates of analysis and chemical inventory sheets.
Beyond simple identification, understanding the structure lets us predict how cyclohexanediaminetartrate might behave. It’s a salt, so solubility in water looks good. Each part of the molecule lends specific traits, setting the stage for its possible uses. Chemistry students spend hours connecting chemical formulas to the 3D structures they build with models for this reason. The hands-on manipulation preps them for real applications, whether they end up in the lab or another science-driven field.
This compound, thanks to its amine groups and tartaric acid background, finds a spot in asymmetric synthesis. Here, it plays a role in chirality—an area chemists obsess over in drug development, since one “handedness” of a molecule can be therapeutic, while the other brings side effects. Cyclohexanediaminetartrate, with its own chiral centers, becomes part of the toolkit for controlling these outcomes. The importance of accuracy in its formula comes up—if the ratio or structure were off, the process could churn out the wrong products.
Safety also connects to knowing these formulas. All chemicals carry potential hazards, and Material Safety Data Sheets rely on proper formulas to list information. Emergency response or waste treatment teams base decisions on what people call the empirical formula—again, C10H20N2O6. Even licensing and transport rules hinge on getting those numbers and letters correct.
For anyone working with cyclohexanediaminetartrate, keeping documentation clean and accurate brings not just peace of mind but legal compliance. Errors in formula on shipping labels or regulatory forms can slow down supply chains or bring fines. In my own work, double-checking formulas isn’t just smart; it’s a habit learned from stories of a single digit making a shipment unsellable.
The importance of understanding this formula doesn’t stay stuck in the lab. From drug synthesis to food production and workplace safety, knowing exactly what cyclohexanediaminetartrate is—and what its formula stands for—keeps the gears of science and industry turning smoothly, safely, and with confidence.
Cyclohexanediaminetartrate doesn’t sound like something a person would bump into at the grocery store. Just the name feels technical, locked into the world of chemists and manufacturers. But for many industries, this compound finds its way into the lab and on to technical datasheets. Folks dealing with specialty chemicals often wonder: Is this stuff dangerous? That’s an important concern, because every chemical carries risks, but not all risks stack up the same way.
Safety data means a lot in the chemical world. Companies and researchers have spent decades putting Cyclohexanediaminetartrate through tests. According to what’s published in safety data sheets, this compound doesn’t earn a spot among the most toxic. It isn’t listed as a carcinogen by agencies like IARC, and regulatory frameworks haven’t put it on any alarming lists. But even a “mild” chemical can cause trouble if ignored. That’s something I learned the hard way, working in a lab where complacency with so-called safe chemicals once turned a minor spill into a real eye-irritation scare.
Just because something isn’t flashing red lights doesn’t mean you can skip caution. Cyclohexanediaminetartrate can irritate eyes and skin. Prolonged contact has the potential to bring on allergic reactions in sensitive folks. The powder form particularly demands respect, as inhaling fine particles of almost anything will lead to trouble for your airways. Chronic exposure, even to substances that seem mild, still raises questions scientists don’t always have answers for—especially over long careers in the same workspace.
Once a chemical leaves the lab, its story doesn’t stop. Waste disposal creates a headache if a substance lingers too long in water or soil. Luckily, research hasn’t flagged Cyclohexanediaminetartrate as a persistent contaminant or a major bioaccumulative threat. A compound that breaks down steadily avoids the long-term scars left by harsher chemicals like PCBs or heavy metals. Still, best practice means capturing waste where possible and not washing it down a sink. This keeps options open for responsible recycling or destruction, something more players in the chemical world are talking about every year.
Day to day, smart chemical safety boils down to the basics many of us learn in school: gloves, goggles, and a working fume hood. Companies that train employees to treat every material carefully keep surprises to a minimum. The worst lab accident I ever saw started with overconfidence about a “safe” compound—a plume of dust that should have been cleaned up right away but wasn’t. Routine checks on air quality and regular reviews of procedures put control back in the hands of workers.
Facts back up a low hazard profile for Cyclohexanediaminetartrate, but people are still the weak link if they tune out after reading the first part of a data sheet. Each new material deserves a real look at its risks, even if it doesn’t bring fearsome labels along for the ride. Staying current, comparing fresh studies against old data, and building a culture where “harmless” doesn’t mean “ignore it”—that proved its worth in every safe lab I ever set foot in.
For anyone handling unfamiliar chemicals, including Cyclohexanediaminetartrate, safety means knowing the facts and not skipping steps. That approach protects people, protects the environment, and keeps the surprises where they belong—in the test tubes, not out on the bench.
Every chemical stored in a lab or facility represents more than inventory; it shapes safety, product reliability, and environmental impact. Cyclohexanediaminetartrate, while not a household name, often plays a key role in synthesis and research. From personal experience working in shared lab spaces, mishandling even small-batch compounds has led to unexpected headaches. Odors spread, glass degrades, or worse, there are emergency calls because of overlooked details.
Cyclohexanediaminetartrate requires real attention to location and conditions. Humidity often leads to clumping or chemical breakdown. I’ve seen open-air storage racks slowly ruin an entire shipment—moisture seeped in, and a year’s effort was wasted. Dry environments don’t just benefit the product's lifespan, they also support consistency batch after batch. Keep this compound in tightly sealed containers, away from windows and other sources of fluctuating temperature.
Cool, stable storage keeps decomposition at bay. In my own work, overheating led to uneven reactions and strange byproducts. Refrigerators or temperature-controlled cabinets shouldn’t be afterthoughts—they’re investments with real returns. Not every facility needs a full climate-controlled warehouse, but the difference between a 22°C stockroom and one that spikes into the 30s shows up in product loss and downtime.
Walk into any credible lab and you’ll see everything labeled, but not all labels actually inform you. It takes just one missed hazard logo to put people at risk. Cyclohexanediaminetartrate, like many organic compounds, can trigger respiratory or skin irritation. At one lab, cross-contamination happened after a rushed intern grabbed an unmarked flask. One minute of care could have avoided a week’s cleanup effort. Labels with chemical name, concentration, date received, and expiry reduce these mistakes, and that comes straight from the trials of managing a rotating team.
The biggest oversights in chemical storage always involve incompatible mixes. Mixing this salt with strong acids, bases, or oxidizers often seeds hazardous reactions. I learned, the hard way, that it’s not just about the chemicals themselves, but the cleaning agents and glassware stored nearby. Build distinct, clearly marked zones for acids, bases, organics, and oxidizers. Use color-coded bins and barrier shelves—what starts as a hassle becomes a habit that saves lives.
Chemical safety never stops at the shelf. Accidental spills demand plans and practice. Spill kits with absorbents and neutralizing agents, along with regular emergency drills, give teams confidence and clarity. My own comfort with emergency protocols didn’t come from reading the Material Safety Data Sheet—it came from drills and conversations with more experienced chemists.
Cyclohexanediaminetartrate doesn’t call attention to itself. It’s just one of many chemicals quietly waiting for a task. Yet proper storage determines if that quiet stays undisturbed or turns into a page in the accident report. Taking time for these basics isn’t academic—lives, research budgets, and reputations depend on it. Anyone handling chemicals owes themselves and their community strict, thoughtful storage.
Cyclohexanediaminetartrate steps into the spotlight more often in labs and among researchers than on the average person’s radar. People running experiments or formulating products count on knowing what happens when this compound meets water. Published data and real-world experience both point in the same direction: cyclohexanediaminetartrate dissolves easily in water. In practical terms, you won’t see it clumping or sitting at the bottom of a beaker for long.
Anyone dealing with a tartrate salt like this one knows how solubility decides more than outcome of a basic mixing test. Water-soluble ingredients help speed up countless chemical reactions. Their solutions stay transparent and uniform, helping researchers get consistent results batch after batch. Poorly soluble salts throw a wrench in the works. They can reduce the available active ingredient or leave residues in equipment, leading to wasted material and skewed results.
Cyclohexanediaminetartrate stands out for dissolving readily. That matters most in settings like pharmaceutical development, where precision and repeatability rule. Years ago, I watched a colleague run a titration series where even slight differences in solubility put entire data sets at risk. Watching your samples crystalize halfway through an assay can drive home the lesson that solubility is not a trivial detail—it’s a foundation for any method relying on aqueous solutions.
Why does this molecule offer good solubility in water? Two key features drive this behavior: the tartrate component has several hydrophilic (water-loving) groups and the cyclohexanediamine unit blends organic and ionic behaviors. Hydrogen bonding pulls the molecule apart as soon as it meets water. This isn’t just a theoretical point: published values and direct experience confirm that, at room temperature, cyclohexanediaminetartrate forms clear solutions up to fairly high concentrations.
Teams working on drug formulation or biochemical assays often use cyclohexanediaminetartrate as a buffer or reactant. In these roles, unreliable solubility drags down yield and disrupts assays. The straightforward dissolution of cyclohexanediaminetartrate cuts down development time. It also brings flexibility to process design, letting developers adjust concentrations up or down to tune reactions.
Lab workers and developers should not overlook purity when using any salt in solution. Even highly soluble materials stir up trouble if contaminated with trace metals or organic byproducts. Ensuring reliable supply and verifying batch quality through certificates of analysis reflects due diligence. Regulatory guidance highlights the need for such vetting, especially in pharmaceuticals and food products. I always check recent literature for any fresh reports on impurities or incompatibilities before scaling up.
If solubility fails to meet your need, tweaks in temperature or use of cosolvents in certain settings can often do the trick. Yet, before moving to those options, double-check water purity. Sometimes hard water or old glassware introduces unseen variables. For those scaling up industrial processes, tighter control over storage and handling of both solid and dissolved forms cuts down unexpected precipitation and keeps processes on track.
Solid science and attention to detail give cyclohexanediaminetartrate a strong reputation among water-soluble compounds. With the right approach, its ease of use can help unlock innovative research and efficient production, provided quality and compatibility keep step with every new batch.
Providing high-quality chemical products and logistics solutions for global trade partners.
