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HS Code |
917040 |
| Chemical Name | Amoxicillin Sodium |
| Formula | C16H18N3NaO5S |
| Molecular Weight | 387.39 g/mol |
| Cas Number | 34642-77-8 |
| Appearance | White to off-white crystalline powder |
| Solubility | Freely soluble in water |
| Storage Temperature | 2-8°C |
| Purity | Typically ≥98% |
| Ph Value | 7.0–8.5 (in 1% aqueous solution) |
| Melting Point | N/A (decomposes before melting) |
| Stability | Light and moisture sensitive |
| Application | Chemical reagent; research use only |
As an accredited Amoxicillin Sodium - Chemical Reagent factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, opaque HDPE bottle labeled "Amoxicillin Sodium - Chemical Reagent, 25g," featuring hazardous symbols, lot number, and storage instructions. |
| Shipping | **Description:** Amoxicillin Sodium – Chemical Reagent is shipped in sealed, moisture-proof containers to ensure stability and purity. Packaging complies with chemical transport regulations. It is protected from light, moisture, and extreme temperatures during transit. Appropriate labeling and documentation are provided for safe handling and receipt at laboratories or research facilities. |
| Storage | **Storage for Amoxicillin Sodium - Chemical Reagent:** Store Amoxicillin Sodium in a tightly sealed container, protected from light and moisture, at temperatures between 2°C and 8°C (refrigerated). Avoid exposure to excessive heat or humidity. Ensure the storage area is well-ventilated and clearly labeled. Keep away from incompatible substances and restrict access to authorized personnel only. Dispose of according to local regulations. |
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Purity 98%: Amoxicillin Sodium - Chemical Reagent with purity 98% is used in microbiological assay validation, where it ensures accurate quantification of bacterial inhibition zones. Molecular Weight 387.39 g/mol: Amoxicillin Sodium - Chemical Reagent with molecular weight 387.39 g/mol is used in pharmaceutical research formulations, where it guarantees precise molar calculations for dose response studies. Stability Temperature 2-8°C: Amoxicillin Sodium - Chemical Reagent with stability temperature 2-8°C is used in long-term laboratory storage, where it maintains potency and minimizes degradation. Water Solubility ≥ 95%: Amoxicillin Sodium - Chemical Reagent with water solubility ≥ 95% is used in injectable solution preparation, where it allows rapid and complete dissolution. Particle Size < 75 μm: Amoxicillin Sodium - Chemical Reagent with particle size < 75 μm is used in analytical sample preparation, where it promotes uniform dispersion for reproducible analytical results. Melting Point 200°C: Amoxicillin Sodium - Chemical Reagent with melting point 200°C is used in thermal stability tests, where it demonstrates suitability for high-temperature process conditions. Endotoxin Level < 0.1 EU/mg: Amoxicillin Sodium - Chemical Reagent with endotoxin level < 0.1 EU/mg is used in cell culture contamination controls, where it prevents adverse cellular responses. |
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In the world of scientific discovery, researchers often look for reliability and consistency, especially in the reagents they use every day. Amoxicillin Sodium, offered here as a chemical reagent, brings a familiar legacy from pharmaceutical settings but now serves the research community. Far from being limited to clinical therapy, its sodium salt form has become a staple for those looking to study antibiotic mechanisms, screen bacterial strains, or investigate resistance in controlled environments.
The product carried here comes in powder form with a typical purity above 98%, set for the needs of rigorous laboratory work. Each lot undergoes stringent quality checks, eliminating most risks of unwanted by-products or heavy metal contamination. The fine, white crystalline structure dissolves easily in water, which means researchers prepare solutions for agar plates or broth assays without waiting ages for powder to go into solution. Amoxicillin Sodium presents a low moisture content and tight control of particle size, so concentration calculations stay consistent from one experiment to the next.
Lab scientists approach every project having to balance cost, reproducibility, and performance. Some competitors market antibiotics designed strictly for clinical injections or oral formulations, where stabilizers and fillers complicate use in the lab. This chemical reagent version strips away those extras—no unnecessary sugars, flavors, or binders that could throw off a microbial growth test or a calibration curve. Cell-culture work and molecular biology applications both benefit, as the active ingredient sees no adulteration or interference from pharmaceutical-grade excipients.
Studies on antibiotic activity in bacteria rely on reagent-grade materials. Clinical tablets, for instance, often carry starch or cellulose, and such substances could cloud a spectrophotometer reading or encourage unwanted growth on selective media. Years spent running microbial inhibition assays make it clear: contaminants turn simple trials into troubleshooting marathons. High-purity Amoxicillin Sodium keeps the variables to a minimum. Control plates stay pristine, and zones of inhibition mean what they are supposed to mean.
Some chemical suppliers will market generic penicillin options that don’t fully disclose salt forms or purity levels. Amoxicillin Sodium, with its sodium counterion, brings water solubility higher than the trihydrate variant. It makes preparing stock solutions fast and foolproof, which matters on a hectic day. Researchers worry less on whether they calculated mass based on anhydrous content or wet weight—the sodium salt brings a predictable molecular weight aimed at repeat experiments. The result? Less error, more meaningful comparisons between batches and labs.
Educational institutes often turn to Amoxicillin Sodium in microbiology labs to teach students about antibiotic resistance. The simple disk diffusion experiments from high school through university carry more credibility with a well-documented reagent. Gram-positive and Gram-negative bacteria both feature in class projects as students chart their sensitivity to beta-lactam antibiotics. Outside teaching, agricultural labs also use this compound in screening plant pathogens or preventing contamination in tissue culture setups. In every case, the need for a product free from preservatives or unlisted chemicals continues to grow.
The trihydrate form, common in oral medications, works fine for human consumption but brings headaches in many lab protocols—excess water content introduces uncertainty during weighing, and solubility often lags behind. The sodium salt, on the other hand, delivers distinct advantages. Its predictable solubility profile pairs well with sensitive assays such as minimum inhibitory concentration (MIC) testing or high-throughput screening platforms. The lack of common pharmaceutical excipients also minimizes false positives and negatives that sometimes creep into microbial assays.
Years in a teaching lab showed how often preparation methods can get tripped up by less-than-ideal reagents. The first time I watched a culture plate overgrow because someone used a tablet ground into powder, I realized the importance of specifying chemical reagent grade products. The sodium salt form survived autoclaving better, saved time in preparation, and offered reliable inhibition zones every single time. Colleagues working in pharmaceutical companies echo that story—development teams screen dozens or even hundreds of beta-lactams, so having a consistent, high-purity amoxicillin sodium ensures their findings hold up in peer review.
Quality matters most under the microscope. Researchers can’t afford unpredictable behavior from reagents when precision defines every publication, grant application, and product launch. Sourcing Amoxicillin Sodium as a chemical reagent rather than crushed tablets pays off in reliability. For example, in work screening soil bacteria for new antibiotics, a single spoilage or poorly dissolved preparation can cost days and skew results toward false-resistant strains. The straightforward solubility and tight tolerance in mass yield steady, reliable inocula even when scaling up processes.
Tableted amoxicillin, while suitable in healthcare settings, brings along binders—things researchers can’t easily account for during quantification. Some labs struggle with unfiltered suspensions or sticky dissolution in water when using trihydrate, and sterile filtering becomes a hassle. By moving to the sodium salt with clearly indicated purity and controlled particle size, filtration becomes easier. Research teams can spend more time optimizing protocols and interpreting data, less on prepping and re-prepping solutions.
One clear pitfall with clinical-grade antibiotics is the lack of full transparency. Missing documentation on exact composition can pose issues—what works for a physician might not serve someone needing a reference standard for analytical chemistry. With Amoxicillin Sodium, you know exactly what enters your experiment. Nothing more, nothing less. This matters whether you’re working in drug development, testing environmental samples for contamination, or building sensitivity maps for pathogens in the food supply.
Storing antibiotics always introduces questions about degradation, especially where short expiry or unpredictable moisture comes into play. Powdered Amoxicillin Sodium, free from carrier matrix and stored in airtight containers, tends to show stability that meets the demands of long-term projects. The absence of moisture-sensitive fillers boosts longevity. It remains dry and flows well, without caking or clumping, which saves time and effort during batch preparation.
Research rarely limits itself to a single organism or protocol. Labs testing environmental samples for resistant organisms, biotech startups developing new diagnostics, or even food safety teams validating pasteurization processes—each one relies on chemical-grade amoxicillin sodium. Unlike clinical material, where regulatory overlays block certain uses, research-focused products arrive free from those limitations. This opens new avenues for innovation whether in public health surveillance or microbial ecology.
At the heart of every robust experiment lies the promise that each component performs as expected. Skimping with low-grade or poorly characterized antibiotic salts introduces pitfalls. Reputations rise and fall on the strength of a data set, and no one wants their next grant application questioned because the “antibiotic effect” came from an unidentified buffer impurity. As reproducibility takes center stage across journals and grant makers, making an informed choice up front pays off.
While Amoxicillin Sodium as a chemical reagent remains outside the scope of clinical prescription, many institutions now demand documented traceability for all research supplies. Laboratories participating in internationally recognized studies or submitting data to regulatory bodies insist on full certification, purity assurance, and clear labeling. Having a product that meets these bars means less time spent justifying procurement decisions and more directed at core research goals.
Undergraduate and graduate educators increasingly specify research-grade antibiotics in their supply lists. This move reflects years of troubleshooting and repeated experiments where uncontrolled impurities led to unexplained results. Choosing high-grade Amoxicillin Sodium sets the next generation up for honest, meaningful science. Students learn the linkage between purity, precision, and reproducibility, a lesson often missed when cost-cutting swaps in consumer-grade alternatives.
Advances in manufacturing bring consistency to research supplies. Modern production of Amoxicillin Sodium includes vacuum drying, fine mesh sieving, and strict contamination checks. This means today’s reagents flow better, resist absorbing atmospheric moisture, and can be handled under standard lab conditions without special tricks or panic about product loss. No one wants to start over after uncovering that a poorly stored antibiotic lost its punch weeks before an important experiment.
Safe handling matters. Labs receive Amoxicillin Sodium in tamper-evident containers with hazard labeling fit for chemical use—not clunky bottles recycled from clinical stock. Written protocols specify waste management, bench hygiene, and accidental spill steps. Education on responsible disposal and spill control keeps everyone safe, especially students or less experienced technicians. Amoxicillin belongs in tightly controlled environments where researchers know how to minimize risk from downstream contamination.
Research environments demand full disclosure. Peer reviewers want to see “Amoxicillin Sodium – chemical reagent, purity >98%” rather than a vague generic claim. Publications in major journals require detailed materials and methods. Ordering the right product helps meet those expectations every time, leaving no room for ambiguity. Audits or replication efforts can proceed smoothly, as paperwork ties lot codes and purity back to original documentation, making science easier to validate and build upon.
Research budgets always run tight. For students or start-up labs, stretching every dollar remains a daily task. There’s a temptation to grab the cheapest penicillin-family antibiotic on the catalog, but repeated failed runs or long troubleshooting sessions eat those savings quickly. The up-front investment in chemical reagent Amoxicillin Sodium pays back in saved labor, reliable timelines, and easier purchasing justification. Buying quality up front often costs less in the long run.
With the rapid spread of antimicrobial resistance, the scientific community faces urgent calls for better understanding, faster screening, and smarter antibiotic stewardship. Tools like pure Amoxicillin Sodium chemical reagent prove their value every day—from exploring new mechanisms in resistance genes to testing the impact of treatment regimes across environmental isolates. The expectations for transparency, reproducibility, and rigor will only rise; preparing with chemical-grade reagents is one of the best ways to meet this future head-on.
Looking back over years spent in both teaching and research environments, the products that most contribute to progress are always the simplest, most predictable, and most reliable. Amoxicillin Sodium, presented as a chemical reagent, fits that description in every respect when compared to clinical material or generic bulk powders. Fewer headaches during setup and fewer “mystery” errors in journals mean more impactful, recordable discoveries. Investing in quality today builds a foundation for tomorrow’s breakthroughs.
The industry doesn’t stand still. Reagent scores get reviewed, batches improve, new production techniques get adopted, and customer feedback drives development. Close collaboration between users and suppliers makes every subsequent release a touch better—easier to dissolve, purer, or subject to stricter testing protocols. Users shape the next generation of lab supplies by voicing what works in practice, which keeps the market tuned to real-world needs instead of repeating yesterday’s mistakes.
In the end, the quality and suitability of Amoxicillin Sodium as a chemical reagent shows up not in the sales pitch but in the clean data flowing from plates and flasks on lab benches. It remains an essential part of any serious research effort into antibiotics and resistance. Whether you are a new student setting out to understand the basics of microbiology or a seasoned investigator seeking to publish high-impact work, the right choice in reagents unlocks better science and fewer setbacks. Having reliable, transparent, and high-quality Amoxicillin Sodium at your side does more than save time; it opens the door to what discovery should really feel like—clear, measured progress through every experiment.
