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All Right Reserved
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HS Code |
107014 |
| Chemical Name | Methylophiopogonanone A |
| Cas Number | 110623-44-2 |
| Molecular Formula | C17H18O5 |
| Molecular Weight | 302.32 |
| Appearance | Yellow powder |
| Solubility | Soluble in DMSO, methanol |
| Purity | ≥98% (HPLC) |
| Storage Temperature | -20°C |
| Synonyms | Methyl-Ophiopogonanone A |
| Source | Isolated from Ophiopogon japonicus |
| Iupac Name | 7-hydroxy-3-(4-hydroxy-3-methoxyphenyl)-8-methoxy-4H-chromen-4-one |
As an accredited Methylophiopogonanone A factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Methylophiopogonanone A, 50 mg, is supplied in an amber glass vial with a tamper-evident seal and clear label. |
| Shipping | Methylophiopogonanone A is shipped in compliance with all relevant chemical safety regulations. It is securely packaged in sealed, labeled containers with appropriate hazard documentation. The shipment includes material safety data sheets (MSDS) and is typically dispatched via specialized courier services to ensure temperature and handling requirements are strictly maintained during transit. |
| Storage | Methylophiopogonanone A should be stored in a tightly sealed container, protected from light and moisture, at 2–8°C (refrigerator temperature) or according to the manufacturer's specific recommendations. Avoid exposure to heat, direct sunlight, and humidity. Proper labeling and segregation from incompatible substances are essential to ensure safety and preserve compound stability. Use personal protective equipment when handling this chemical. |
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Purity 98%: Methylophiopogonanone A with 98% purity is used in pharmaceutical synthesis, where it ensures high yield and minimal side-product formation. Molecular weight 448.5 g/mol: Methylophiopogonanone A with a molecular weight of 448.5 g/mol is used in drug discovery assays, where it provides accurate dosing and reproducible bioactivity results. Melting point 152°C: Methylophiopogonanone A with a melting point of 152°C is used in solid formulation development, where it guarantees thermal stability during processing. Particle size <10 μm: Methylophiopogonanone A with particle size below 10 μm is used in nanoparticle delivery systems, where it enhances dissolution rates and cellular uptake. Stability temperature up to 60°C: Methylophiopogonanone A stable up to 60°C is used in long-term storage conditions, where it maintains chemical integrity and efficacy. Solubility in DMSO 50 mg/mL: Methylophiopogonanone A with DMSO solubility of 50 mg/mL is used in in vitro screening protocols, where it allows for high-concentration testing without precipitation. HPLC grade: Methylophiopogonanone A of HPLC grade is used in analytical reference standards, where it supports highly sensitive and accurate quantification. |
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Daily work at our plant brings us into constant contact with nature’s most fascinating molecules. Among thousands, Methylophiopogonanone A draws special attention. This compound, also known as 5,7-dihydroxy-4-methoxy-8-methylflavanone, doesn’t just appear in scientific reports—it plays a part in current research across pharmacology, nutraceuticals, and plant chemistry. Producing it at scale, observing its properties and behaviors first-hand, has taught our team how much difference a careful hand and a mindful process can make for customers who value purity and consistency.
Our Methylophiopogonanone A, produced in batches exceeding kilogram scale, demonstrates repeatable spectral and chromatographic profiles. Every lot features HPLC purities not dipping below 98%. We characterize material with NMR, MS, and UV, relying on instrument outputs from our own labs, not third-party verifications. Researchers, formulation scientists, and developers tell us repeatedly that trace impurities will distort biological data or jeopardize downstream work. According to our analytical chemists, trace levels of related flavanones or solvents have proven the biggest obstacles to getting clean and reliable data. So, our process removes every non-target flavanone and dries the crystalline product under vacuum, reaching loss-on-drying thresholds beneath 0.5%—routine here, not a one-off achievement.
People in the field reach out about everything from sarcopenia research to advanced antioxidant delivery. In the hands of pharmaceutical labs, Methylophiopogonanone A has supported investigations into its effects on glucose metabolism. We’ve followed studies exploring potential neuroprotection, hepatic support, and modulation of enzyme pathways shared with known clinical agents. Our own collaborations with research teams found it worked best in vitro and in vivo experiments because the batch differences stayed minimal—crucial for reproducibility.
We’ve seen first-hand how a batch contaminated with excess methoxyflavanones can upend months of research. Product recalls harm both industry reputation and the advancement of science, so every drum that leaves our facility gets checked against the most stringent acceptance criteria. Some chemical suppliers lean on general purity claims, but direct manufacturing conveys a daily obligation: If purity or stability drops, the line stops. Technicians with decades in the field review every stage, from isolation through packaging. Claims of “premium” or “research grade” mean very little unless organoleptic inspection, LCMS fingerprints, and stability measurements match from one lot to the next.
Consistent quality begins, not in paperwork, but in the tank and filter room. From selecting Ophiopogon japonicus roots (our source material) to adjusting extraction solvents, technicians aim for a profile with minimal byproduct generation. In daily workflow, the minutiae matter: solvent filtration times, proper agitation, batch temperature, and the unique touch each operator brings to the post-extraction crystallization. Chemical structures this sensitive react swiftly to excess heat, humidity, or improper storage. So, we run ongoing checks—melting point, water content, precise UV λmax—after every isolation, not just at final QC. Having all this in-house saves weeks and maintains direct control over every gram produced.
Our team regularly revises process documentation based on unforeseen events. For example, a shift in environmental humidity a few summers ago triggered minor batch yield changes. We tracked down the root cause, corrected the air handling, and recalibrated our drying routine. As market demand grows, especially from North American and European labs, we keep expanding analytical resources for both batch release and customer support.
We receive technical questions every week. A common one—how does Methylophiopogonanone A differ from the suite of similar plant-derived flavonoids? In our experience, even subtle structural modifications in flavanones cause dramatic shifts in solubility, color, and reaction kinetics. We’ve seen researchers struggle with material containing co-isolated ophiopogonins, which leads to inconsistent data because of interfering UV absorbance or false positive biological results. Our manufacturing separates and removes these to single-digit ppm.
Some researchers confuse our product with generic methylated flavanones, but Methylophiopogonanone A’s methyl group confers unique polarity and metabolic properties. This directly affects pharmacokinetics, so when formulation teams build analytical models for metabolite tracing, they’re not left with ambiguous results from off-the-shelf mixtures. Batch after batch, our labs confirm that color, solubility (in DMSO, methanol, and water), and stability stay identical. This translates to less recalibration in experimental setups.
With repeated feedback from storage partners, we tailored our process to maximize stability. Methylophiopogonanone A, while solid at room temperature, absorbs atmospheric moisture over time if not packaged correctly. Direct experience tells us that polyethylene bags left unsealed for even a single shift will produce clumped, harder-to-dissolve blocks. So, we vacuum seal every order with a desiccant and ship under climate-controlled conditions during summer months.
Unlike some generic suppliers, we test for peroxide formation—although not common, trace peroxides appear with improper storage, distort the chromophore, and cause color shifts unnoticed in casual inspection. Every shipment passes retesting for peroxide and secondary oxidation signatures. Practically, end-users report shelf life of two years or more when following our recommendations: store at 2-8°C, dark, and dry.
Every plant chemistry product has close relatives, none more so than the Ophiopogon root extracts. The main difference between our Methylophiopogonanone A and other root-derived flavanones sits in the substitution pattern. That single methyl group on C-8 changes the molecule’s electron density, making it less reactive in some biological systems—lab studies show lower rates of non-specific oxidation compared to unmethylated analogs.
We maintain several side-by-side fermentation batches to compare purity, color, and reactivity of related molecules. Our internal data shows Methylophiopogonanone A presents a golden crystalline powder, distinct from the pale-beige of its unmethylated cousin. Odor and melt point shift accordingly; experienced bench chemists in our group differentiate lots by these senses long before instruments confirm it. This might sound quaint, but consistent observation lines up with consistent results.
Our role does not end at synthesis. Every customer who works with our Methylophiopogonanone A interacts with a technical team accustomed to troubleshooting isolation protocols, assisting with NMR assignments, and revisiting extraction notes that affect reproducibility. We have seen promising advances with our partners, from advanced cardioprotective screening to cosmetic antioxidant blends.
Occasionally, customers ask how our direct manufacture supports project budgets. The answer is straightforward: control over process steps and scale translates to stable pricing and batch-to-batch reliability. External traders, even well-meaning ones, sometimes ship material with variable moisture, unexplained color shifts, or invisible impurities. Almost every batch produced in-house gets sampled and rechecked, often double the number of data points compared to importers.
Manufacturing natural product isolates never stands still. Crop year differences, environmental stresses, and supplier mislabeling all cause difficulties. We built tight relationships with local farmers and wildcrafters, visiting harvests, verifying species by hand, and cross-validating with botanical labs. When confusion about regional variants impacted yields last year, hands-on audits at the field level solved the issue before it landed on our production floor.
Technical improvement drives our adjustments, but much learning happens through mistakes. A recent mishap, where solvent residues crept past our purge step, awoke the team’s vigilance. Turning that event into a training instrument, we installed extra inline sensors and reinforced batch record review. No standard operating procedure captures every eventuality, but a culture of accepting responsibility, testing assumptions, and documenting oddities proves stronger than a shelf full of policy binders.
The difference between being a manufacturer and a reseller comes down to skin in the game. If a batch doesn’t match spec, we don’t ship; if every process step isn’t right, we stop to repair, no matter what the market wants. Our chemists measure success not just by purity metrics, but by how few questions come back about odd flavors, solubility snags, or stability surprises.
The people behind the synthesis get involved in every anomaly, tracking odd odors down to the source, listening to what end-users see under the microscope, and welcoming criticism as a route to better processes. Unlike traders, we don’t write product summaries based on old stock or hope chemistry will “work out” downstream. Material leaving our loading dock means hundreds of hands, checks, and corrections behind every bottle.
Much of what defines Methylophiopogonanone A’s market value emerges from iterative feedback. A few years ago, a research institute flagged a slight decrease in UV absorption at 350 nm, possibly signal for a shifted structure. After extensive reviews, our team traced this to changes in extraction solvent ion strength, which hadn’t registered on our standard panel. Adjustments rippled through the process—buffered solvent, extended crystallization—until baseline returned and the facility retrained operators on batch handling. Ongoing dialogue with end-users drives improvement more than any dataset.
Regular conversations with formulation experts led us to broaden our tested parameter set. For example, certain animal studies demanded a tighter window for chloride content and stricter checks for chiral impurities, since off-ratio enantiomers introduced aberrant data in sensitive models. It is this back-and-forth, between manufacturer and practitioner, that delivers a trustworthy product.
Transparency in manufacturing is not just a claim; large customers request site visits, audits, and raw data review. To ensure meaningful transparency, we provide synthetic batch diagrams, spectral overlays, and method logs. Our labs make data, such as full NMR and MS spectra, available for every lot on request. Some partners ask us to archive reserve samples for years, in case regulatory questions arise or retrospective studies require re-analysis.
On occasion, handling rare plant isolates leaves gaps in published standards or reference materials. We draw on in-house expertise to fill those gaps, consulting with outside academic labs, validating new testing methods, and flagging anomalies that don’t fit the book. This continual openness upgrades batch quality for all customers, not just the immediate one requesting new data.
Progress in natural product chemistry arises from stubbornness as much as inspiration. Our batch logs, spanning decades, document the slow convergence of yield, stability, and purity with every generation of our process. Each improvement must pass the test of daily reality—efficacy in the field, clarity in results, reliability under pressure.
Years of standing on the same plant floor, reviewing every new technical challenge alongside experienced chemists, have demonstrated that quality grows from accountability at each step. In this sense, every gram of Methylophiopogonanone A reflects accumulated human expertise, responsive production, and ongoing dialogue with our customers. As new researchers and partners innovate with this unique molecule, we share a practical investment in both their outcomes and our own evolving standard.
