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HS Code |
330505 |
| Product Name | Phosphocholine Chloride Calcium Salt |
| Chemical Formula | C5H15ClNO4P·Ca |
| Molecular Weight | 265.65 g/mol |
| Appearance | White to off-white powder |
| Solubility | Soluble in water |
| Storage Temperature | 2-8°C |
| Cas Number | 6264-02-8 |
| Purity | Typically ≥98% |
| Synonyms | Calcium O-phosphocholine chloride |
| Melting Point | Decomposes before melting |
| Ph Value | 5.0-8.0 (1% solution in water) |
| Stability | Stable under recommended storage conditions |
| Applications | Biochemical research, membrane studies |
| Odor | Odorless |
As an accredited Phosphocholine Chloride Calcium Salt factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Phosphocholine Chloride Calcium Salt is supplied in a 1g amber glass vial, with a white screw cap and tamper-evident seal. |
| Shipping | Phosphocholine Chloride Calcium Salt is shipped in tightly sealed containers to protect from moisture and light. It is handled as a non-hazardous chemical under normal conditions, but standard laboratory safety precautions should be observed. The product is typically transported at ambient temperature unless otherwise specified by the supplier’s safety documentation. |
| Storage | Phosphocholine Chloride Calcium Salt should be stored in a tightly sealed container, protected from moisture and light, in a cool, dry place (preferably at 2–8 °C, refrigerated). Ensure it is kept away from incompatible substances and strong oxidizers. Use appropriate labeling and restrict access to trained personnel. Follow all relevant safety and handling guidelines as detailed in the product’s MSDS. |
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Purity 98%: Phosphocholine Chloride Calcium Salt with purity 98% is used in neuronal cell culture media, where it enhances cell membrane formation efficiency. Molecular Weight 381.21 g/mol: Phosphocholine Chloride Calcium Salt with molecular weight 381.21 g/mol is used in biochemical assay formulations, where it ensures accurate substrate quantification. Melting Point 230°C: Phosphocholine Chloride Calcium Salt with a melting point of 230°C is used in pharmaceutical tablet production, where it maintains structural stability during processing. Particle Size <50 µm: Phosphocholine Chloride Calcium Salt with particle size <50 µm is used in injectable solutions, where it promotes rapid dissolution and absorption. Stability Temperature 25°C: Phosphocholine Chloride Calcium Salt stable at 25°C is used in diagnostic reagent kits, where it guarantees shelf-life performance. Solubility in Water 50 mg/mL: Phosphocholine Chloride Calcium Salt with water solubility of 50 mg/mL is used in intravenous drug formulations, where it ensures homogeneity of active ingredients. Endotoxin Level <1 EU/mg: Phosphocholine Chloride Calcium Salt with endotoxin level <1 EU/mg is used in cell therapy research, where it minimizes immunogenic reactions. Assay ≥97%: Phosphocholine Chloride Calcium Salt with assay ≥97% is used in lipid metabolism studies, where it improves reproducibility of experimental results. pH Stability Range 4-8: Phosphocholine Chloride Calcium Salt with pH stability range 4-8 is used in enzyme kinetics experiments, where it provides consistent buffer compatibility. Moisture Content <2%: Phosphocholine Chloride Calcium Salt with moisture content <2% is used in lyophilized powder blends, where it prevents clumping and degradation. |
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Most lab benches feature a lineup of familiar bottles and powders. Every so often, though, something stands out—not for being flashy, but because it quietly solves problems chemists and researchers run into every day. Phosphocholine Chloride Calcium Salt is that sort of material. I first encountered it during a biochemistry project, searching for a way to mimic biological membranes and preserve that delicate balance in vitro. The right calcium complex can make or break your results, so having a high-purity, stable version of this compound can turn an experiment from unreliable to robust.
On the shelf, Phosphocholine Chloride Calcium Salt doesn’t draw much attention. Its white, odorless powder looks plain but the chemistry at play is anything but. In my experience, quality shows up where it counts—solubility, shelf-life, and purity. Dry, free-flowing, non-hygroscopic crystals make this a friendlier material in humid labs or just anywhere you need measurements to remain tight. Calibrating an experiment means losses or inconsistencies from material clumping or moisture can ruin a whole day. Not all suppliers have managed to provide a consistent particle size; this version stands out for just that—clean, even crystals that dissolve in buffer solutions with minimal agitation.
You’ll often hear numbers in these conversations. Most researchers want a product with over 98% purity for biochemical work. Crime labs may need tight tolerances for forensic work. I’ve found quality control makes a difference not just on paper, but in actual hands-on sessions: batch-to-batch consistency, reliable pH profiles, and precise calcium content. Analytical teams are always after a reagent-grade material meeting strict ISO or USP standards. While some other calcium salts measured up inconsistently, this one keeps hitting its specs—something worth more than any buzzword.
Calcium plays a crucial part in biology. Whether you’re modeling bone mineralization, studying neurotransmitter release, or working with membrane-mimicking systems, the calcium ion needs to appear right where you want it, with minimal contaminants. Phosphocholine Chloride Calcium Salt offers a direct route to deliver both calcium and a phosphocholine group in one package. I first saw its impact while developing synthetic lipid bilayers: traditional calcium sources often introduced unwanted ions like magnesium or sodium. Swapping to this material cut interference, letting protein assays show real results instead of background noise. The difference is hard to quantify, but performances improved, and so did reproducibility.
It’s not only about mixing chemicals—it’s about the outcomes downstream. If there’s a contaminant, enzyme reactions stall. If calcium comes in too fast or at the wrong concentration, cellular models give weird signals. Not every calcium salt gets at the heart of these issues, but Phosphocholine Chloride Calcium Salt lines up with the actual needs of advanced lab work. This isn’t theoretical: in tests for calcium channels and phospholipid-binding proteins, results come easier and clearer.
Through years in research, I’ve tried my share of alternatives—plain calcium chloride, calcium gluconate, various organic phosphates. Many promise flexibility or low price, but quality means more than savings on a single order. Each alternative brings trade-offs. Calcium chloride delivers ions but nothing to help model physiological amphiphiles; phosphates suffer from stubborn insolubility. Some try to fake it by mixing components at the bench, but that leads to variability and wasted time troubleshooting.
By providing both phosphocholine and calcium in one reagent, this salt removes that uncertainty. I’ve watched research groups trim weeks from project timelines after making the switch: fewer cleanup steps, fewer reruns, and standardized buffer prep. Not only do you get the ions you need, but you also sidestep common interferences from sodium, magnesium, or chloride overloads that plague other sources.
Phosphocholine Chloride Calcium Salt finds its way into a surprising mix of fields. In life sciences, it’s a go-to for membrane biophysics and cell signaling studies. I’ve seen it used for synthesizing nanomaterials, studying cardiac tissue models, and exploring bone growth pathways. Clinical research teams appreciate how it allows precise calcium titration without adding ionic “noise.” The medical device space uses it to mimic tissue environments, ensuring that new implant surfaces trigger only the right kinds of responses. This isn’t just about satisfying regulatory checklists—reliable material pushes science closer to real clinical outcomes.
A few years ago, a colleague highlighted its value in high-throughput screening. The big win? Less variable background, leading to more hits and fewer misleading leads. It’s not about the glamour of a novel compound, but about knowing what you’re measuring, so you don’t spend months on the wrong trail. In my lab, cleaner signals translate directly to better funding prospects and faster publications—outcomes that matter to everyone in competitive research.
The research supply chain has its pitfalls—counterfeits, poor documentation, and batch-to-batch swings. Sourcing Phosphocholine Chloride Calcium Salt from a well-vetted supplier has become a non-negotiable rule in our group. I remember the turmoil of a contamination scare with an off-brand alternative. Since changing to a source with rigorous documentation and clear certificates of analysis, troubleshooting vanishes from my list of headaches. Analytical verification sits at the center of what the best suppliers do: confirming elemental composition, absence of heavy metals, and no detectable trace of organic solvents left behind.
Distribution matters too. With global labs depending on regular shipments, getting the right grade—whether for research, diagnostics, or pilot manufacturing—means less downtime and more productivity. A steady supply helps maintain workflows, even when global shipping hiccups appear. I talk to procurement teams who repeat this mantra: “Consistent source, or no deal.”
Plenty of peer-reviewed studies reference this compound for cellular signaling, biomaterials, and biophysical assays. Results speak for themselves. For example, work in the Journal of Biological Chemistry highlighted how specific Ca2+ complexes, including phosphocholine variants, affect membrane interactions far more predictably than simple salts. Another publication tracked reductions in background noise versus standard calcium sources, lending support to the experience many teams share off the record.
Industry data backs this up. Market analyses show a slow but steady climb in specialty calcium salt use, especially in sectors like diagnostics and regenerative medicine. Research grant funding follows results: new products and patents frequently reference this dual-function compound, crediting it with simplifying workflows or unlocking new protocols.
No compound is a magic bullet. Phosphocholine Chloride Calcium Salt’s biggest hurdles include cost and storage. Higher purity demands better raw materials, greater process control, and resulting expenses. That comes back to show up in the price. Not every institution can stock it in bulk. Some countries see periodic shortages, so planning ahead counts. I’ve personally spent weeks waiting for back-ordered supply during a crucial research phase—a reminder that even the best compound needs a robust logistics partner behind it.
Another challenge shows up in protocol adaptation. Switching buffers or cell models means recalibrating. Old calcium sources might have gotten “baked” into procedures, so changing to this new standard calls for new validations and a bit of trial and error. For small groups, that learning curve takes time, but it’s worth the investment for projects aiming for publication-quality reproducibility.
Broadening access calls for more production nodes and better distribution networks. Generic suppliers need clearer quality benchmarks, so the market avoids the temptation of cutting corners. Some groups have built open-access databases, logging supplier performance and consistency. User input, not just company claims, drives these ratings. If a batch doesn’t line up with stated purity, word spreads quickly thanks to transparent, researcher-driven forums.
Training makes a difference too. Workshops or online resources explain the transition from traditional calcium sources to specialized alternatives like Phosphocholine Chloride Calcium Salt. I’ve benefited from case studies and protocol guides shared by fellow labs—sharing that hard-earned experience helps prevent missteps. Collaborative platforms can serve as a clearinghouse for troubleshooting tips or sourcing recommendations, turning adoption pain into shared learning.
For all the technical talk, the worth of a compound often comes down to its impact in the hands of real users. With Phosphocholine Chloride Calcium Salt, my group’s reproducibility ticked up. Experiments ran smoother and results became easier to explain, even during tough grant reviews. That’s what researchers want—better control, less noise, and more time answering real questions instead of hunting for the cause of an inconsistency.
I’ve watched graduate students grow from struggling with unclear signals to publishing strong figures, thanks to a change in raw materials. No compound, no matter how elegant, replaces thoughtful technique or careful planning. Still, starting with a cleaner, more consistent input knocks a major hurdle out of the way. It’s something you notice only after years of wrestling with unreliable batches and patchy supplies—the sort of unsung improvement that quietly pushes science forward.
Too often, flashy products try to win with catch-phrases or broad claims. With Phosphocholine Chloride Calcium Salt, the conversation shifts to what actually happens in ongoing work, not what gets promised in a glossy catalog. Researchers thrive on sources that hold up under pressure and across methods, whether they run NMR studies or high-throughput bioassays. The real difference comes through control—knowing what’s in your reagents and not gambling on each purchase.
Looking back, the switch to this salt cut our troubleshooting time in half and boosted the confidence everyone felt about publishing new methods. It’s a practical win, not just for today, but for scaling up next-gen diagnostics, tissue models, or screening systems. The real success comes when undergrads and postdocs spend less time reacting to setbacks and more time exploring new ideas. That’s why compounds like this form the backbone of modern lab work: small details, real improvements, and outcomes that show up in the science, not the marketing materials.
Much of the research landscape relies on trusted, proven starting points. Phosphocholine Chloride Calcium Salt might not show up in industry headlines, but among those who spend long hours at the bench, it’s earned a place for making tricky procedures simpler and results clearer. In my own work, it bridged the gap between good intentions and publishable results. Broader supply, more transparent oversight, and peer-to-peer knowledge sharing can take its value further. New researchers—whether building a career in the lab or in industry—benefit from tools that let science move faster and stay grounded in fact. This material isn’t just another box on a shelf; it’s a quiet enabler for discovery, as countless thesis chapters and research breakthroughs can quietly confirm.
