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HS Code |
969167 |
| Chemical Name | Simvastatin Ammonium Salt |
| Cas Number | 1343901-54-9 |
| Molecular Formula | C25H38O5 · NH4 |
| Molecular Weight | 434.58 g/mol (simvastatin base); include NH4 for salt |
| Appearance | White to off-white powder |
| Solubility | Soluble in DMSO, methanol |
| Storage Temperature | -20°C (recommended) |
| Purity | Typically ≥98% (HPLC) |
| Application | HMG-CoA reductase inhibitor, cholesterol-lowering agent |
| Synonyms | Simvastatin ammonium salt, CI-781 |
As an accredited Simvastatin Ammonium Salt factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Simvastatin Ammonium Salt, 1 gram, is supplied in a sealed amber glass vial with a tamper-evident cap and clear labeling. |
| Shipping | Simvastatin Ammonium Salt is shipped in tightly sealed containers, protected from moisture and light. The chemical is handled according to standard safety protocols, typically packaged in insulated, leak-proof packaging. Transport is conducted under ambient conditions unless otherwise specified, complying with regulations for non-hazardous pharmaceutical compounds. Includes appropriate labeling and documentation. |
| Storage | Simvastatin Ammonium Salt should be stored in a tightly closed container, protected from light and moisture. Maintain storage at -20°C or below in a dry, well-ventilated environment. Avoid exposure to heat and incompatible materials. If available, refer to the product's Safety Data Sheet (SDS) for specific storage instructions to ensure stability and prevent degradation. |
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Purity 98%: Simvastatin Ammonium Salt with purity 98% is used in pharmaceutical formulation optimization, where high purity ensures consistent bioavailability and efficacy in lipid-lowering drugs. Molecular Weight 441.56 g/mol: Simvastatin Ammonium Salt with molecular weight 441.56 g/mol is used in drug metabolism studies, where precise molecular mass supports accurate pharmacokinetic profiling. Stability Temperature up to 40°C: Simvastatin Ammonium Salt with stability temperature up to 40°C is used in extended storage applications, where thermal stability maintains potency during transit and warehousing. Particle Size <10 μm: Simvastatin Ammonium Salt with particle size less than 10 μm is used in tablet manufacturing, where fine granulometry enhances uniform mixing and dissolution rates. Hydrophilic Index 78%: Simvastatin Ammonium Salt with hydrophilic index 78% is used in aqueous drug dispersions, where increased solubility improves delivery in oral formulations. Melting Point 121–125°C: Simvastatin Ammonium Salt with melting point 121–125°C is used in heat-sensitive compounding processes, where controlled melting behavior ensures product integrity. Assay ≥ 99%: Simvastatin Ammonium Salt with assay not less than 99% is used in quantitative analytical calibration, where high assay value guarantees reproducibility in HPLC testing. Residual Solvent <0.1%: Simvastatin Ammonium Salt with residual solvent content below 0.1% is used in regulatory-compliant drug production, where minimal solvent presence meets safety and purity guidelines. |
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Pharmaceutical development often circles back to molecules that have already proven their value in the clinic. Simvastatin has stood out for decades as a cornerstone cholesterol-lowering medication, and many still see it as a tried-and-true choice. But research keeps moving. Today, Simvastatin Ammonium Salt offers researchers and manufacturers a tool that builds on years of clinical trust but opens fresh avenues for discovery and formulation.
Simvastatin Ammonium Salt stands as a derivative of the original simvastatin molecule. Chemists designed this compound with the intent to address basic needs in synthesis, preparation, and handling. This salt form brings changes in how the molecule dissolves, stores, and interacts with other chemicals, creating a reliable option for both laboratory and production environments.
The product typically appears as a white to off-white powder. Purity levels hover at pharmaceutical grade, comfortably meeting the expectations of most R&D and industrial environments. The salt is stable enough to endure standard shipping and storage but stays manageable in common solvents. These qualities help technicians side-step some of the practical hurdles faced with base simvastatin or alternative forms, such as calcium salts.
The original simvastatin had some quirks. While effective in the body, the raw compound’s low water solubility often complicated laboratory work. Suspension, mixing, and dosing all get easier with improved solubility. By pairing simvastatin with ammonium, scientists produced a version that dissolves readily under neutral or slightly acidic lab conditions. This means fewer headaches in preparing test solutions, less need for specialized solvents, and cleaner results in bioassay or biochemical studies. The streamlined process frees up time and lowers the risk of introducing errors during sample prep.
Many modern research projects depend on being able to quickly test, modify, or combine molecules. With the ammonium salt, researchers avoid making tough choices about how best to deliver a stubborn compound into a biological system. Pharmacologists and formulation specialists can work with smaller volumes and simplify downstream processing. In my own experience, the challenge of working with a poorly soluble material is a source of frustration and lost time. Anything that removes barriers in this step often yields better study outcomes and faster cycles of learning.
To decide on this product, it helps to look at the alternatives. Simvastatin usually comes in its free acid form or as a calcium salt. Each form has a story. The free acid can be tough to work with in water-based systems and may come with some stability challenges. Calcium salts, common in the world of statin manufacturing, have their own handling benefits, but they still fall short on solubility, which ends up limiting flexibility in how scientists run their tests or create experimental formulations.
Researchers aiming for consistent results sometimes turn to ammonium salts for their gentle profile. The ammonium counter-ion does not complicate interpretation of results in pharmacokinetic or pharmacodynamic studies. In contrast, using metal ions—like calcium—sometimes introduces variables or unwanted interactions, especially for teams studying the biochemistry at a deeper level. Having worked in a lab that compared salt forms of numerous actives, I saw studies take unexpected turns because a secondary ion in the formulation ended up changing cell behavior, rather than the drug itself. That experience drills home the need for clean, clear research tools.
Developers rely on Simvastatin Ammonium Salt both at the early screening stage and as projects ramp up towards pilot production. The solid, free-flowing powder is easy to measure and doesn’t clump or degrade quickly in the typical med-chem lab setting. People handling dozens of test compounds a week appreciate having one less stability concern to manage. Its enhanced solubility accelerates cell-based assays and helps ensure dosing accuracy in animal studies. This is not just a matter of convenience—a margin of error in dosing or dissolution can snowball into flawed data, failed hypotheses, or even drawn-out investigations to troubleshoot problems that never needed to exist.
On the manufacturing front, formulation experts view Simvastatin Ammonium Salt as a problem-solver. Some advanced dosage forms—like injectable suspensions or nanoparticles—demand a material that can disperse predictably and remain consistent from batch to batch. The salt’s dependable solubility and stability answer these needs without adding complexity to excipient selection or compounding. In cases where teams are developing next-generation delivery systems, such as long-acting injectables or transdermal products, flexibility in raw material is key. With this product, project managers face fewer constraints in formulation design, giving them more shots on goal in a tight development timeline.
Across the board, safety in pharmaceutical development can never be far from the conversation. Ammonium salts, including Simvastatin Ammonium Salt, share a long history of safe use in regulated pharmaceutical settings. Chemical stability means lower risk of breakdown products appearing during storage, and elevated solubility lessens the odds of dosing errors related to incomplete mixing or unexpected precipitation in solution. In both preclinical and clinical research, minimizing surprises in chemistry reduces downstream risk to human volunteers and patients. Experiences in QC labs stress this point—unexpected impurities cost time, resources, and sometimes lead to programs getting scrapped late in the game. Relying on a product with fewer such variables helps research teams spend less energy on damage control and more time on learning and progress.
Modern R&D programs often operate under pressure to adapt. One month may call for small-scale bench studies, and the next will demand preparation on a pilot-scale level. Simvastatin Ammonium Salt adapts well because it fits easily into pre-existing workflows. Analytical chemists get predictable retention and quantification profiles in HPLC or LC-MS studies. In downstream work, process engineers can scale up test batches without needing to overhaul established protocols. Products that can move with a program from discovery to late-stage development allow teams to sidestep expensive revalidation cycles or last-minute project redesigns.
I recall sitting on project review committees where change in raw material format forced us to rerun stability studies or redo toxicology tests due to a late-game switch in salt forms. Products like Simvastatin Ammonium Salt, which remain consistent from small scale to large, remove many barriers and keep program budgets more manageable. In competitive fields, that small margin is sometimes what separates a successful candidate from one that gets left behind.
Basic researchers rely on well-characterized compounds that behave predictably from well to well or animal to animal. At the molecular level, simvastatin itself modulates HMG-CoA reductase, blocking a key step in cholesterol synthesis and affecting cardiovascular risk. Scientists building from this foundation want to test analogues, combinations, or delivery strategies. Having an ammonium salt form in hand simplifies experiment setup and increases confidence in published results. Instead of wrestling with solubility quirks or impurity spikes, teams get cleaner data and fewer repeat experiments. Labs teaching new scientists benefit, too—trainees produce reliable results with less specialized supervision.
In translational medicine, bridging animal data to clinical settings relies on reducing variables wherever possible. Using a salt form with reliable solubility and chemical behavior ensures that small differences in formulation won’t swamp out true biological signals. Consistency lays the groundwork for evidence that stands up to peer review, grant scrutiny, or regulatory audit. The extra certainty in how simvastatin behaves helps turn bold ideas into actionable therapies that actually reach people who need them.
Cost pressures are a reality in both small startup settings and multicenter industrial operations. Though minor on paper, the efficiency gains from easy-to-handle materials scale up quickly. Simvastatin Ammonium Salt takes less solvent, less time for dissolution, and less energy spent in troubleshooting. I’ve heard from procurement specialists who compare solvent, storage, and waste costs across similar molecules—and the more practical format wins almost every time. Research budgets get stretched further, and more resources can go into new avenues rather than backfilling for inefficiencies.
Waste disposal also enters the equation. Solutions that dissolve more fully cut down on hazardous residue, reduce cleaning cycles, and simplify compliance. In highly regulated pharmaceutical settings, every gram of hazardous waste saved translates to lower regulatory and environmental management costs.
Universities and teaching labs appreciate products that help students gain real-world skills. Handling difficult powders or troubleshooting dissolutions creates roadblocks that eat into already short lab periods. Simvastatin Ammonium Salt avoids many such issues. In one program I worked with, students switched from a poor-solubility statin to the ammonium salt form and saw higher success rates in their analytical chemistry modules. This let instructors focus on advanced concepts, not just basic technique troubleshooting. A more accessible material means more students can engage with hands-on pharmaceutical development and gain practical skills before entering the workforce.
Pharmaceutical research keeps evolving as teams push into new delivery platforms, personalized therapies, and complex biological systems. These trends demand materials that can keep up. Simvastatin Ammonium Salt, with its easier solubility and predictable behavior, offers an adaptable option for these modern studies. As more research moves into complex models—like organ-on-chip platforms or high-throughput combinatorial systems—the demand for materials that dissolve quickly, don’t interfere with new technologies, and produce clean results only grows.
From experience, the frustrations with legacy forms of core actives taught teams to look for more sensible alternatives early in project planning. The switch to an improved salt form might seem like a minor step, but the resulting benefits compound across different study phases. The capacity to move seamlessly from screening to formulation is a concrete advantage. A well-behaved salt form can mean the difference between a program that adapts with the science and one slowed by legacy chemical quirks.
As regulatory bodies and quality standards progress, a growing trend favors drug substance consistency, traceability, and safety. Simvastatin Ammonium Salt stands well-positioned to support this direction. The stability, solubility, and handling benefits it provides match up with the ongoing shift toward “ready-to-use” materials in pharmaceutical production. I have observed that QA auditors and compliance officers increasingly look for raw materials that reduce sources of variability and demonstrate well-established safety profiles. Companies that adopt these salt forms early on often face fewer regulatory questions and can produce quality documentation with less rework.
Drug development moves fast, and delays linked to raw material issues quickly erode confidence both in house and among partners. Adopting materials that prevent these slowdowns helps both small biotechs and large pharma outfits reach key milestones and funding triggers. Based on peer discussions across academic and private sector consortia, the benefit of more predictable materials has started to move from anecdotal lab stories into formal process change across the industry.
Some research teams express caution in switching from legacy forms, often due to institutional inertia or existing stockroom supply chains. Sharing real-world outcomes from laboratories and manufacturing lines that have adopted Simvastatin Ammonium Salt can help change this picture. Public forums, symposia, and informal collaborations among scientists speed this spread of knowledge.
Vendors and academic groups that provide detailed analytical data, case studies, and clear comparisons support broader adoption across research settings. This culture of transparency aligns with industry-wide movements towards quality, reproducibility, and cooperative science. Over time, adoption will likely reach beyond high-end pharmaceutical labs into community research spaces and teaching hospitals.
No product completely solves every technical problem. Some advanced applications might still require tweaks or supplemental handling strategies—particularly at the extremes of high-throughput screening or ultra-scale manufacturing. But the track record and broad fit of Simvastatin Ammonium Salt reduce the range of situations where convoluted workaround methods become necessary. Ongoing documentation, improved distribution, and open dialogue between users and suppliers can address hurdles as they appear.
The move toward improved salt forms like this one signals a broader shift in pharmaceutical supply chains and research habits. As product portfolios evolve, there is room to further enhance properties such as solubility, stability, or ease of use. Events like user-group meetings or collaborative projects will push suppliers to continue responding to real-world lab and production challenges. Over time, variable handling headaches that once seemed unavoidable will become a thing of the past.
Simvastatin Ammonium Salt arrives as more than just another chemical option—it acts as proof of how basic improvements in format and handling can ripple through the entire pharmaceutical development process. Research teams and production engineers working with statins no longer have to accept unnecessary friction in their workflow. Instead, they gain a practical and responsible alternative that connects decades-old clinical insights to the next generation of experimental medicine.
From undergraduate teaching labs up through global drug development programs, this accessible product helps scientists, engineers, and clinicians translate ideas into action with fewer delays, better data, and greater impact. The story of its uptake in labs and factories echoes a broader lesson in scientific work: simple changes in material choice can free teams to focus on the questions and answers that really move the needle for human health.
