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All Right Reserved
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HS Code |
992341 |
| Productname | Isoorientin |
| Casnumber | 4261-42-1 |
| Molecularformula | C21H20O11 |
| Molecularweight | 448.38 g/mol |
| Appearance | Yellow powder |
| Solubility | Soluble in methanol, ethanol, DMSO; slightly soluble in water |
| Meltingpoint | >300 °C (dec.) |
| Purity | ≥98% (HPLC) |
| Synonyms | Luteolin-6-C-glucoside |
| Source | Plant derived (e.g., passion flower, bamboo leaves) |
| Storagetemperature | 2-8°C |
| Chemicalclass | Flavonoid |
| Smiles | C1=CC(=C(C=C1C2=C(C(=O)C3=C(C2=O)C(=C(C=C3)O)O)O)O)O |
| Uses | Analytical reference, pharmacological studies |
As an accredited Isoorientin factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Isoorientin, 10 mg, is packaged in a clear, labeled glass vial with a secure screw cap, sealed for laboratory use. |
| Shipping | Isoorientin is shipped in tightly sealed, chemical-resistant containers to protect against moisture and light. Packaging complies with international chemical transport regulations. During transit, the product is handled by certified carriers specializing in hazardous materials, ensuring safe, secure delivery with appropriate labeling and accompanying documentation such as safety data sheets (SDS). |
| Storage | Isoorientin should be stored in a tightly closed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Recommended storage temperature is typically 2–8°C (refrigerated conditions). Avoid exposure to direct sunlight, strong acids, and bases. Proper labeling and secure storage away from incompatible substances help ensure product stability and prevent contamination or degradation. |
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Purity 98%: Isoorientin with purity 98% is used in antioxidant assays, where it enhances free radical scavenging activity. Molecular weight 448.38 g/mol: Isoorientin with molecular weight 448.38 g/mol is used in anti-inflammatory research, where it effectively inhibits cytokine production. Particle size <50 μm: Isoorientin with particle size <50 μm is used in tablet formulations, where it ensures uniform dispersion and bioavailability. Stability temperature up to 40°C: Isoorientin stable up to 40°C is used in nutraceutical product development, where it maintains potency during storage. Melting point 265°C: Isoorientin with melting point 265°C is used in crystalline reference standards, where it provides reliable thermal analysis. UV absorbance λmax 350 nm: Isoorientin with UV absorbance λmax 350 nm is used in HPLC quality control, where it allows for precise quantification. Solubility in ethanol 10 mg/mL: Isoorientin with solubility in ethanol 10 mg/mL is used in liquid extract formulations, where it ensures homogenous incorporation. HPLC grade: Isoorientin HPLC grade is used in pharmaceutical analysis, where it guarantees high-purity chromatographic separation. Residual solvent <0.1%: Isoorientin with residual solvent <0.1% is used in injectable preparations, where it meets safety and regulatory standards. Polymorphism Form I: Isoorientin in polymorphism Form I is used in crystallography studies, where it supports reproducible structural characterization. |
Competitive Isoorientin prices that fit your budget—flexible terms and customized quotes for every order.
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Every time we step into our production facility, we’re plugging into a tradition of innovation rooted in science and respect for botanical resources. Isoorientin is more than a product line number for us—it reflects years of dedication to extraction, purification, and in-depth study of how plant flavonoids perform in advanced manufacturing environments. In an industry where purity and reliability open doors, Isoorientin stands as a testament to what careful synthesis and process control can achieve.
Our team focuses exclusively on manufacturing Isoorientin from specialized natural sources, primarily through controlled plant extraction methods followed by fine-tuned chromatographic separation. As a plant-based C-glycosylated flavone, Isoorientin brings a unique structure to the table—a configuration that biochemists recognize for its solubility and stability. We measure purity by HPLC, batch after batch, achieving levels above 98%, so inconsistencies don’t slip through unnoticed into your end-use applications.
Many products that fall under the broad category of “flavonoids” lack the specificity labs and formulators need for controlled formulation work. Isoorientin, by contrast, offers documented molecular integrity, distinct from its close relatives like orientin and vitexin. The additional hydroxyl group in Isoorientin drives measurable differences in antioxidant capability and reactivity in physical chemistries, especially when incorporated in health, analytics, or food system applications.
Our output model covers several packaging formats and grades. The most requested is a highly refined, white-to-light-yellow powder delivered in moisture-resistant containers, in quantities that suit research, pilot, and industrial scales. All batches pass stringent tests for botanical origin, moisture content, and chromaticity. Because we refine directly from plant starting material—without synthetic shortcuts—minute natural nuance remains, but our processing cuts unwanted byproducts like excess polyphenols and sugars to below threshold levels.
Stability testing takes center stage for us; with regular simulated transport analysis, Isoorientin shipments reach clients worldwide still within spec for both potency and flow properties—these details matter most to chemists and formulators scaling up from benchtop to market.
In the early 2000s, most of the requests we handled for plant flavones came from academic labs. Today, industry looks much broader—food-tech, cosmeceuticals, and pharmaceuticals now ask not only for pure Isoorientin, but for robust documentation, safety data, and traceable sourcing. Each sector leverages Isoorientin’s chemistry in specific ways.
Nutritional companies integrate Isoorientin for its antioxidant features. Instead of vague health claims, our collaborators back their formulations with clinical research linking specific biomarkers of oxidative stress attenuation to Isoorientin-rich compounds. Compared to generic flavone mixtures, single-molecule Isoorientin allows for quantifiable dosage and predictable interaction with other formulation components.
Food chemists often highlight how Isoorientin influences shelf-life extension and color stabilization. Since our material resists thermal degradation better than many similar compounds, bakery and beverage companies use it in product lines aiming for both clean-label distinction and tested functionality. We work with global QA teams to ensure our Isoorientin mixes seamlessly into aqueous and lipid environments without precipitating or causing haze—solubility profiles monitored from lab to large-scale filling lines.
Researchers in dermatological formulation see opportunity in Isoorientin too. Its molecular shape seems particularly suited for tackling mechanisms involved in inflammation and UV-response, according to published mechanistic studies. Integrating our consistent isolate means researchers can test hypotheses without adjusting protocols for purity drift or unexpected derivatives. This reliability sets professionally manufactured Isoorientin apart from bulk botanical extracts, which frequently vary season by season.
Reverse phase HPLC standardization runs as part of our daily routine—not because regulators demand it, but because internal benchmarks guide our process optimization. For analytical labs, we document retention times, UV absorption spectra, and impurity cut-off points so method development moves swiftly. We participate in method round-robins to compare our material’s performance against global standards, aligning with professional best practices found in peer-reviewed journals.
In bioactivity screening labs, especially in the pharmaceutical space, purity directly shapes data quality. Low-level contaminants in generic flavone extracts (seen with TLC as undefined bands) can throw off in vitro and in vivo readouts. Our Isoorientin batches undergo profiling for common plant impurities—apigenin, luteolin, and other C-glycosyl flavones—to make sure these don’t skew pre-clinical or quality control studies. When a new research group reaches out about a project, our technical staff can walk through chromatographic profiles and batch histories without hedging; transparency has earned us repeat partnerships over the years.
While orientin and isoorientin display structural similarities, their biochemical behaviors diverge with even slight molecular modifications. Isoorientin’s extra hydroxyl group at the 3’ position increases hydrophilicity, which leads to a slightly increased solubility in polar solvent systems. Our chromatography analyses show sharper separation from derivatives like vitexin and isovitexin, which contain differences on the B-ring and sugar attachment points. We back up these distinctions with mass spectroscopy and NMR profile archives that confirm identity and rule out cross-contamination or mix-up during the extraction process.
Because of these distinctions, applications requiring strict antioxidant profile control will see meaningful differences in product performance. Color retention in processed foods, reduction of oxidation-mediated degradation in skin-care products, and tighter control of in vitro assay performance—these are tangible operational impacts Isoorientin can deliver where other generic plant flavones fall short.
Sourcing integrity is under rising scrutiny. Our approach starts far upstream, working directly with partner farms that cultivate the target plant species under strict agricultural standards. These relationships avoid the usual pitfalls of inconsistent sourcing: interrupted availability, shifts in plant phytochemical balance, and adulteration risk.
Cradle-to-factory traceability has become the backbone of our supply chain. All plant material batches come tagged with season, region, and harvest data, which syncs up with our internal tracking system once shipments reach our doors. This granular level of oversight allows responsive adjustments to extraction parameters year to year, minimizing the risk of chemical variability often reported in the literature.
Waste management also features prominently in our operations. Plant residue from Isoorientin extraction doesn’t head to landfill—it reenters local industrial compost streams or is converted to bioenergy, depending on feasibility and regulatory context. We monitor energy consumption during extraction and purification, investing in closed-loop solvent recovery systems to bring down both carbon footprint and cost of production.
Ongoing engagement with sustainability certifications—organic, fair trade—gives our partners and customers more insight into not just what we make, but how we work. These choices don’t just reflect values—they buffer business against supply shocks and regulatory shifts, too, which makes for smoother long-term operations for everyone in the supply chain.
Our customers range from solo academic researchers to multinational manufacturing plants. Everyone expects more than a COA and a spec sheet—they want assurance that behind the material, a robust process stands ready to handle questions, provide technical support, and document batch histories.
Audit trails record every key step, from biomass arrival through bottling. As requirements for regulatory filing get steeper, especially in food and pharma, we supply full documentation packages: plant origin certificates, allergen statements, non-GMO declarations, and validated analytical methods. On-site technical staff remain available for follow-up during QA audits and downstream process troubleshooting.
Some clients run comparative trials, pitting Isoorientin against orientin or synthetic standards. We actively encourage this, standing by our data not only with numbers, but with open access to archived chromatograms and instrument logs. This approach doesn’t just foster confidence—it lets new users integrate Isoorientin into complex projects faster, cutting learning curves and reducing batch rejection rates tied to ingredient variance.
Innovating with Isoorientin means more than shipping product out the door. Our R&D wing collaborates regularly with external research groups to test new extraction technologies, stability enhancers, and integration into emerging application fields. We back these efforts with our own grant funding, sharing co-authorships on white papers and participating in academic conferences.
Upstream, we keep lines open with botanists, geneticists, and agricultural extension teams to adapt to evolving climate and cultivation conditions. Downstream, our application specialists regularly field calls from food technologists, analytical chemists, and product developers troubleshooting unforeseen solubility or reactivity quirks. This culture of transparency keeps us learning and iterating, so future Isoorientin batches reflect not just purity, but performance insights gathered from real-world trials.
Sustaining consistent plant supply and controlling batch-to-batch variability represent daily challenges. Nature doesn’t behave like a chemical reactor; even with perfect field techniques, plant secondary metabolite concentrations shift with weather, soil, and time of harvest. Our lab constantly refines extraction and pre-processing steps, adjusting solvent blends, flow rates, and temperature curves based on compositional data harvested from each new delivery.
Quality assurance also remains front and center. A spike in interest for Isoorientin several years ago prompted copycat materials, some of which failed identity or purity testing on import. We stepped up HPLC fingerprinting and origin checks at the point of entry for all third-party samples, rejecting out-of-spec consignments and reporting counterfeit findings to industry authorities. This vigilance protects both end-users and our own reputation.
Regarding regulatory trends, shifting standards for natural ingredient labeling and novel food designation generate a level of paperwork unseen just a decade ago. We keep a compliance officer on staff and maintain membership in technical working groups, so rule changes or emerging documentation requirements never land as last-minute surprises. These steps let us keep our material available to partners advancing new therapeutic, food, and personal care lines.
Many Isoorientin samples in circulation today come from bulk botanical extraction companies offering wide product ranges but little in-depth process specialization. Our advantage comes from decades spent engineering and refining flavonoid isolation techniques. We know which resin beds best capture Isoorientin, which temperature ramps optimize yield, and where to look for minor glycoside contamination that could affect sensitive downstream use.
The investment in process control translates to fewer surprises in customer operations. Instead of shifting your protocols every time a new barrel arrives, Isoorientin from our lines delivers the same profile time after time—backed by technical support and science-based documentation.
Smaller producers may elect for lower investment in analytical technology or training, which opens risk for trace contamination or mislabeling. We run duplicate inspection regimes, verifying plant material identity through both botanical and chemical tests and running spot-checks at key inflection points throughout the year. This “trust but verify” culture makes our Isoorientin an ingredient not just for today’s standard but tomorrow’s innovation.
Looking ahead, demand for traceable, reliable, and high-purity plant-based ingredients continues to build. Emerging uses in green industrial chemistry, advanced materials, and clinical applications hint at new directions for Isoorientin, beyond classic roles in nutrition and food stabilization. Our in-house research team scouts novel functionalities, looking to partner with groups exploring cross-disciplinary projects—functional textiles, biosensors, biocompatible packaging, and more.
We’re adapting our process toolbox to integrate green chemistry methodologies and new bioreactor-based approaches for future Isoorientin lines. Cross-department workshops and external industrial partnerships keep our expertise current and make room for scalable solutions that prioritize both product integrity and environmental responsibility.
Operating as a direct manufacturer brings with it a sense of responsibility, not only in terms of product purity and batch consistency, but in technical transparency and authentic partnership. Each batch of Isoorientin that leaves our plant comes with years of development, strict adherence to process integrity, and shared learning gathered from every partner in our network.
We see Isoorientin’s future as tightly linked with the needs of researchers, formulators, and innovators worldwide. By holding fast to high standards and open technical engagement, we are making it possible for this single molecule to play its part in shaping safer, smarter, and more sustainable solutions for the challenges ahead. Each day in the lab, our work reflects the value of science applied with care, and the belief that reliable ingredients drive real-world progress.
