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All Right Reserved
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HS Code |
380167 |
| Product Name | 3,4,5-Tricaffeoylquinic Acid |
| Chemical Formula | C34H28O16 |
| Cas Number | 2450-53-5 |
| Appearance | Yellowish to brownish powder |
| Solubility | Soluble in methanol, ethanol, and DMSO |
| Purity | Typically ≥98% |
| Storage Temperature | 2-8°C, protect from light |
| Synonyms | Isochlorogenic acid C |
| Source | Found in various plants, including coffee and artichoke |
| Application | Phytochemical research, antioxidant studies |
| Uv Absorption | λmax ~ 325 nm (in methanol) |
| Stability | Stable under inert atmosphere, sensitive to light and heat |
| Ph Range Stability | Stable in neutral to slightly acidic conditions |
As an accredited 345-Tricaffeoylquinic Acid factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass vial containing 50 mg of 345-Tricaffeoylquinic Acid, labeled with product name, purity, batch number, and safety information. |
| Shipping | 345-Tricaffeoylquinic Acid is shipped in securely sealed containers to prevent contamination and moisture exposure. It is transported under cool, dry conditions, with appropriate hazard labeling. Each package includes a Certificate of Analysis (CoA) and Safety Data Sheet (SDS) to ensure regulatory compliance and safe handling during shipping and delivery. |
| Storage | 345-Tricaffeoylquinic Acid should be stored in a tightly sealed container, protected from light and moisture, and kept at a temperature of -20°C or lower. Ensure the storage area is well-ventilated and free from incompatible materials such as strong oxidizers. Always handle under proper laboratory safety protocols to maintain stability and prevent contamination or degradation. |
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Purity 98%: 345-Tricaffeoylquinic Acid with purity 98% is used in pharmaceutical formulation development, where it ensures consistent bioactivity and therapeutic efficacy. Molecular weight 678.5 g/mol: 345-Tricaffeoylquinic Acid with molecular weight 678.5 g/mol is used in drug screening assays, where precise molecular profiling facilitates targeted compound identification. Stability temperature 4°C: 345-Tricaffeoylquinic Acid with stability at 4°C is used in biological specimen preservation, where prolonged compound stability supports extended shelf life. Particle size <10 µm: 345-Tricaffeoylquinic Acid with particle size less than 10 µm is used in nanoformulation research, where improved dispersibility enhances bioavailability. HPLC grade: 345-Tricaffeoylquinic Acid, HPLC grade, is used in analytical chemistry calibration, where high purity ensures accurate quantitative analysis. Melting point 210°C: 345-Tricaffeoylquinic Acid with a melting point of 210°C is used in thermal stability studies, where resistance to decomposition supports robust product formulation. Optical rotation -12°: 345-Tricaffeoylquinic Acid with optical rotation -12° is used in stereochemical analysis, where enantiomeric purity verification is required for regulatory compliance. Solubility in ethanol 50 mg/mL: 345-Tricaffeoylquinic Acid with solubility in ethanol at 50 mg/mL is used in liquid extract preparation, where efficient solubilization enhances process efficiency. |
Competitive 345-Tricaffeoylquinic Acid prices that fit your budget—flexible terms and customized quotes for every order.
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Work in a chemical manufacturing facility gives a unique perspective on every batch that comes off the line. Every product that we develop, including 345-Tricaffeoylquinic Acid, reflects thousands of hours perfecting procedures, responding to quality control feedback, and adjusting raw materials for consistency. Through this lens, we understand not only the chemical itself, but why researchers, formulators, and product developers rely on strict controls during every step of the process.
In the case of 345-Tricaffeoylquinic Acid, nothing gets overlooked. We see many requests for this molecule originating from teams investigating polyphenols and their applications. Botanical researchers often look for tricaffeoylquinic derivatives because of their occurrence in certain plant species and their role in pharmacological testing. Only rigorous purification protocols ensure the compound matches the expected profile: proper isomer, verified structure, and quantifiable purity. Every operator along the production line keeps an eye out for even minor deviations. Even a shift in pH during the isolation process could influence downstream performance, so regular analytics drive our corrections long before a problem leaves the plant.
The specific model of 345-Tricaffeoylquinic Acid we supply comes out of our precision extraction and synthesis chain. Our facility deals directly with phenolic acids and ester derivatives. The most common form we offer is as a crystalline powder, bottling it only after confirming an HPLC purity over 98%. Many customers choose us specifically for the absence of common plant contaminants and for our batch analysis transparency. Once isolated, the sample holds well under normal conditions, but refrigeration preserves its profile for long-term storage. Each batch carries a COA (certificate of analysis) issued by our own analytical staff, including spectral data from both NMR and LC-MS.
Working in the chemical plant, we see how this molecule differs from analogues such as caffeic or chlorogenic acids. Tricaffeoylquinic’s three caffeoyl groups bonded to a quinic acid core draw some special interest from natural product chemists. Because its biosynthesis requires more steps than mono- or dicaffeoyl forms, we regularly face yield challenges in plant extraction streams. We compensate with post-extraction purification, using a mix of preparative chromatography and fine solvent handling to push out interfering residues. The final compound offers a richer profile in polyphenolic assays compared to simpler phenolic acids.
Another difference comes down to practical usability. Synthetic routes, though labor-intensive, sometimes produce traces of positional isomers. For researchers conducting fine biological assays, isomeric purity is everything. To catch these, our QC lab routinely integrates both spectrometry and chromatographic fingerprinting, screening for those subtle signals that can make all the difference in reproducibility. Our process doesn’t leave the plant manager guessing about what ended up in the bottle.
From our position as the manufacturer, we don’t just hand over a spec sheet and move on. There’s a steady flow of feedback from academic groups, food developers, and cosmetics formulators. One group used our tricaffeoylquinic as a standard in high-throughput screening for radical scavenging, citing the predictable retention time on C18 columns. Another company leveraged its antioxidant signal to justify new blends for botanical extracts in functional foods. We’ve seen the molecule used as a biomarker for quality control in plant breeding programs, which means our assurance of repeatability directly supports these downstream efforts. Some pharmaceutical R&D teams are following up on the compound’s potential anti-inflammatory or neuroprotective effects in cell culture studies. Each demand pushes us to keep checks tight and specs clearly communicated.
Because polyphenolic esters are notoriously prone to isomerization and hydrolysis, our lab sees ongoing refinement. Sometimes, a truckload of raw plant material shows a different polyphenol profile than forecasted. That’s when years of production experience come in. Our team reviews the fractionation data, swaps out solvent ratios, or lengthens the chromatographic run to chase away unwanted peaks. Results are immediately confirmed through MS and NMR. In some facilities, skipping these steps can lead to deliveries full of off-target isomers or extraneous tannins. Our operation puts time and people into every critical checkpoint to keep outcomes reliable—a promise that matters for teams blending, testing, or formulating with our tricaffeoylquinic as a foundation.
It’s common to find our 345-Tricaffeoylquinic Acid in labs developing phytochemical fingerprints for herbal extracts. For teams building dietary supplement profiles, only well-characterized polyphenolics pass the regulatory tests. We collaborate with these groups, sharing method validation data and handling technical questions directly. Our line operators and analytical chemists often coordinate batch reserves for stability testing or re-supply, helping researchers meet their publication deadlines or batch production quotas. In one instance, a client adjusting dosage levels for a plant-based nutraceutical found an outlier in HPLC peaks; our team retraced the batch, checked archived spectral results, and resolved the uncertainty so their study could move ahead with confidence.
Years in chemical manufacturing taught us how valuable customer feedback is for keeping quality on point. Lab reports from the field sometimes flag a trace impurity, or an unidentified spectral shoulder. We drill down, compare results against our in-house reference samples, and walk through data logs to find the issue source. In one production run, a slightly prolonged solvent wash actually raised the purity above our internal specs, while in another, reducing extraction temperature cut out a known by-product. These iterative improvements don’t come from a template—they’re the product of real data and troubleshooting long after the last shift leaves each evening.
Each time our process shifts for a special order, we document the adjustment, double-check the outcome, and add those results to our control documentation. Over time, these records let us push for even tighter tolerances, which helps newer orders benefit from all the lessons learned before. The workflow rarely stands still, because each customer’s application may require unique assurances about compatibility with their own raw materials, solvents, or analytic platforms.
Delivering a drum of tricaffeoylquinic acid isn’t the line’s final chore. We keep a digital archive of every batch produced, cataloging it with full spectral and chromatographic logs. If a regulatory inspection or product recall arrives months down the road, our team can retrieve the necessary data within hours to support traceability. Having our analytical chemists engaged at every production stage ensures each exit certificate reflects the true quality, not just a snapshot. As compliance with international regulations tightens, such documentation grows even more vital for customers managing cross-border supply chains or entering new markets with botanical actives.
Some clients need kilogram orders, others request only a few milligrams as a reference sample. Running a production facility means designing flexibility into our schedule. We set up small-batch runs for high-purity demands and scale up batches for industrial partners. This dual capability draws on both human expertise—location of critical control points, hands-on chromatographic setup—and automated handling that keeps overnight runs efficient. Whether an order calls for a dry, crystalline output or a low-water content for direct formulation, we document each configuration and make that data available to customers upon request.
The real challenge arises with specialty requests, such as rare isomer forms or custom-purity targets. In these cases, our synthetic staff may adjust the esterification steps, deploy different solvent systems, or repack a batch immediately post-purification to avoid environmental moisture uptake. Frequent communication between production, analytics, and the customer’s technical team guides these orders, avoiding surprises and shaving off days from trial-to-full order cycles. Over time, these relationships build a foundation of trust grounded in technical accuracy and the willingness to adjust as each project requires.
Every technician entering the plant sees hands-on machinery, chromatographs, and analytics before touching a production batch. Regular refresher courses on equipment maintenance, new analytical standards, and updated synthesis methods keep skills sharp. We share lessons from QA audits and regulatory site visits. These internally-driven education efforts translate into more reliable results. It’s clear to us that no automation or recipe sheet replaces direct experience in production chemistry. Our quality reflects a living process, not a set of static controls.
Over the years, as more researchers publish findings on this compound, the questions coming to our QC desk also shift. Early requests centered on raw purity. Now, we see more detailed inquiries about minor structural variants, stability after formulation, or interaction with other extractive fractions. Having a dedicated support team embedded in our own facility—chemists who followed the batch from raw material to finished product—allows us to answer quickly and accurately. We recognize that no research or product line stands still, so our ongoing process improvements keep pace with published literature and regulatory trends. Adjustments to our method, prompted by scholarly papers or field reports, become part of the cycle that produces every subsequent lot.
The global supply scene has changed over the last decade. Certain botanical raw materials for tricaffeoylquinic acid synthesis now come with periodic shortages or variability thanks to seasonal weather or changes in source geography. We counteract these swings by building supplier relationships across regions and keeping buffer stocks on hand. Each incoming lot gets screened for target analyte content and secondary compounds. During years where a specific plant source drops in quality, our chemists may pivot extraction protocols or begin producing synthetically in-house to keep up with demand. Transparency in our supply network and real-time updates to our plant floor help prevent disruptions from affecting customer timelines.
Compliance has become more complex as the recognition of bioactive compounds moves into both supplement and pharmaceutical spheres. Regulatory authorities in multiple regions established strict requirements for specific marker compounds, including tricaffeoylquinic acid, beyond basic identity or purity claims. Our own compliance officers interact with health authority queries, supply chain audits, and customer documentation requests. We integrate real-world feedback from these channels into in-plant training and documentation procedures. As a result, regulators respond positively to our recordkeeping and proactive approaches to quality concerns, which strengthens trust with all supply chain partners.
We pay attention to the environmental impact of synthesis and extraction waste. Wherever possible, solvent recovery and recycling operations cut down on plant effluent and reduce disposal costs. Teams across departments collaborate to identify ways to tighten resource efficiency. Regular reviews with local environmental agencies, engineering partners, and NGO groups keep our plant aligned with recognized best practices. Over the years, implementing these practices built efficiencies that both lower operational costs and lift industry standing for conscientious production.
By producing 345-Tricaffeoylquinic Acid ourselves, we maintain intimate control over every aspect of its profile. This makes a difference on several fronts: our customers know they’re not exposed to halfway intermediaries adding markup or muddying traceability. Our technical support staff offers direct feedback to customers, based on firsthand experience, not relayed notes. Each challenge in isolating polyphenols deepens our team’s understanding and pushes improvements into every subsequent batch. Every interaction with external labs or development partners gives a new channel to refine, adapt, and communicate about the product itself.
Many labs pushing the boundaries in polyphenol research deal with interruptions, whether from inconsistent supply or underqualified technical support. Our approach puts reliability at the forefront. Our commitment runs deeper than simply putting a product on the market; long-term relationships grow out of honesty, traceability, and a willingness to engage on complex questions. Teams working on bioanalytical validation experiments, new plant varieties, or product launches for functional foods can depend on a steady, well-characterized ingredient that meets regulatory and research needs. We encourage open channels for technical input and are always ready to discuss new requirements or share further data from upcoming production runs.
Day-to-day experience manufacturing 345-Tricaffeoylquinic Acid demonstrates the value of operational transparency and direct engagement with those applying our product. Each run through the plant adds another layer of experience—time spent troubleshooting a synthesis batch, reviewing analytics, or collaborating with researchers using our materials in cutting-edge studies. This ongoing cycle of production, feedback, and continuous improvement drives value for the whole supply chain—and keeps us invested not just in today’s batch, but in the shared growth of scientific and commercial innovation that tricaffeoylquinic acid helps support.
